EXPOCODE cruise date StationID BottleID LATITUDE LONGITUDE depth Temperature Salinity NO3_plus_NO2 SRP DOP DOP_flag region method reference nd BIOSOPE 2004-10-28 21 21 -8.32545 -141.27521 5.6 27.793 35.56 1.54 0.39 0.21 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-10-28 21 18 -8.32545 -141.27521 15.1 27.773 35.559 1.54 0.42 0.18 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-10-28 21 16 -8.32545 -141.27521 20.8 27.764 35.559 1.54 0.42 0.19 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-10-28 21 14 -8.32545 -141.27521 30.6 27.755 35.558 1.59 0.41 0.21 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-10-28 21 12 -8.32545 -141.27521 40.2 27.745 35.558 1.59 0.41 0.21 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-10-28 21 10 -8.32545 -141.27521 49.7 27.742 35.558 1.64 0.41 0.22 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-10-31 36 22 -8.99582 -136.84779 5.3 27.76 35.615 1.49 0.29 0.29 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-10-31 36 18 -8.99582 -136.84779 20.4 27.715 35.614 1.59 0.30 0.27 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-10-31 36 16 -8.99582 -136.84779 29.7 27.709 35.616 1.54 0.29 0.29 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-10-31 36 14 -8.99582 -136.84779 40.2 27.671 35.621 1.59 0.31 0.27 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-10-31 36 10 -8.99582 -136.84779 60.5 27.577 35.627 1.64 0.32 0.28 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-10-31 36 6 -8.99582 -136.84779 80.4 27.293 35.719 1.54 0.37 0.24 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-03 53 20 -11.73528 -134.09633 9.8 27.805 35.833 nd 0.31 0.24 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-03 53 18 -11.73528 -134.09633 24 27.696 35.975 0.05 0.26 0.30 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-03 53 16 -11.73528 -134.09633 39.2 27.559 36.001 0.09 0.22 0.34 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-03 53 14 -11.73528 -134.09633 49.3 27.503 36.003 0.09 0.22 0.31 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-03 53 11 -11.73528 -134.09633 69.9 27.424 36.016 0.14 0.23 0.30 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-03 53 8 -11.73528 -134.09633 91.7 26.864 36.435 nd 0.25 0.29 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-04 57 19 -13.55333 -132.10686 15.485 27.501 36.135 0.00 0.21 0.29 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-04 57 17 -13.55333 -132.10686 30.076 26.847 36.344 0.00 0.21 0.28 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-04 57 15 -13.55333 -132.10686 40.937 26.738 36.381 0.00 0.22 0.26 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-04 57 13 -13.55333 -132.10686 59.685 26.23 36.581 0.00 0.22 0.25 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-04 57 10 -13.55333 -132.10686 80.657 25.818 36.582 0.00 0.22 0.23 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-04 57 7 -13.55333 -132.10686 99.957 25.417 36.551 0.00 0.24 0.18 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-05 61 19 -15.5343 -129.92754 14.9 27.068 36.338 0.05 0.19 0.27 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-05 61 17 -15.5343 -129.92754 35.3 26.87 36.33 0.05 0.20 0.25 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-05 61 15 -15.5343 -129.92754 45.1 26.593 36.383 0.09 0.21 0.23 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-05 61 13 -15.5343 -129.92754 65.1 26.437 36.496 0.05 0.20 0.23 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-05 61 10 -15.5343 -129.92754 84.2 26.069 36.552 0.05 0.18 0.21 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-05 61 7 -15.5343 -129.92754 108.5 25.459 36.551 0.05 0.20 0.19 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-06 65 19 -17.23447 -127.97176 20.2 26.487 36.533 0.00 0.21 0.22 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-06 65 16 -17.23447 -127.97176 40.1 26.114 36.566 0.00 0.22 0.20 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-06 65 14 -17.23447 -127.97176 60.2 25.991 36.574 0.00 0.24 0.18 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-06 65 11 -17.23447 -127.97176 79.7 25.887 36.574 0.00 0.19 0.22 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-06 65 8 -17.23447 -127.97176 105.2 25.413 36.576 0.00 0.20 0.20 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-06 65 5 -17.23447 -127.97176 141.6 24.592 36.474 0.10 0.19 0.36 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-07 69 19 -18.74717 -125.55151 19.2 25.657 36.531 0.00 0.16 0.27 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-07 69 16 -18.74717 -125.55151 39.2 25.372 36.582 0.00 0.17 0.26 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-07 69 14 -18.74717 -125.55151 54.8 25.275 36.584 0.00 0.15 0.26 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-07 69 11 -18.74717 -125.55151 79.8 24.634 36.541 0.00 0.15 0.24 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-07 69 8 -18.74717 -125.55151 104.8 24.002 36.432 0.00 0.19 0.19 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-07 69 6 -18.74717 -125.55151 132.7 22.513 36.157 0.44 0.22 0.18 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-08 72 19 -20.45467 -122.89305 25.1 24.519 36.386 0.00 0.14 0.19 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-08 72 16 -20.45467 -122.89305 55.6 24.33 36.391 0.00 0.15 0.22 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-08 72 14 -20.45467 -122.89305 74.6 24.325 36.398 0.05 0.16 0.21 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-08 72 12 -20.45467 -122.89305 84.7 24.321 36.402 nd 0.15 0.20 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-08 72 8 -20.45467 -122.89305 124.8 23.511 36.267 0.00 0.14 0.20 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-08 72 5 -20.45467 -122.89305 149.9 22.815 36.142 nd 0.15 0.19 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-09 76 19 -22.05007 -120.38205 19.8 24.277 36.4 0.05 0.14 0.20 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-09 76 16 -22.05007 -120.38205 40.6 24.227 36.432 0.05 0.14 0.20 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-09 76 14 -22.05007 -120.38205 59.3 24.077 36.399 0.00 0.15 0.20 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-09 76 11 -22.05007 -120.38205 79.7 23.145 36.198 0.00 0.13 0.19 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-09 76 8 -22.05007 -120.38205 109.6 22.418 36.069 0.00 0.12 0.18 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-09 76 5 -22.05007 -120.38205 140.3 21.738 35.943 0.00 0.13 0.15 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-10 80 19 -23.55372 -117.88925 30.8 23.385 36.318 0.00 0.13 0.17 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-10 80 16 -23.55372 -117.88925 59.6 23.042 36.314 0.00 0.15 0.15 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-10 80 14 -23.55372 -117.88925 81 22.4 36.137 0.00 0.13 0.16 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-10 80 8 -23.55372 -117.88925 139.3 22.094 36.172 0.00 0.22 0.08 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-10 80 5 -23.55372 -117.88925 178.7 20.57 35.816 0.15 0.19 0.11 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-12 88 19 -25.96975 -114.00505 29.7 22.079 36.029 0.00 0.13 0.13 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-12 88 17 -25.96975 -114.00505 41 22.079 36.031 nd 0.12 0.15 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-12 88 14 -25.96975 -114.00505 69.3 21.892 36.062 0.00 0.12 0.14 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-12 88 12 -25.96975 -114.00505 89.5 21.596 36.009 0.00 0.13 0.13 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-12 88 10 -25.96975 -114.00505 120.1 20.754 35.848 0.00 0.12 0.17 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-12 88 7 -25.96975 -114.00505 187.1 19.103 35.515 0.15 0.19 0.30 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-20 121 19 -27.77275 -107.28623 29 21.283 35.923 0.00 0.12 0.13 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-20 121 16 -27.77275 -107.28623 62.1 21.179 35.957 0.00 0.14 0.11 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-20 121 14 -27.77275 -107.28623 90.5 20.832 35.945 0.05 0.13 0.14 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-20 121 12 -27.77275 -107.28623 120.9 20.428 35.857 0.00 0.14 0.13 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-20 121 7 -27.77275 -107.28623 199.4 19.223 35.548 0.07 0.16 0.11 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-21 125 12 -28.53627 -104.308 105.7 20.023 35.761 0.00 0.13 0.12 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-21 125 10 -28.53627 -104.308 140.9 19.556 35.647 0.00 0.13 0.12 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-21 125 7 -28.53627 -104.308 183 18.103 35.258 0.10 0.14 0.10 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-22 129 19 -29.2252 -101.48098 25.1 19.985 35.478 0.00 0.12 0.15 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-22 129 16 -29.2252 -101.48098 50.5 19.219 35.461 0.00 0.12 0.15 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-22 129 14 -29.2252 -101.48098 64.8 18.982 35.436 0.00 0.12 0.16 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-22 129 12 -29.2252 -101.48098 88.9 18.536 35.365 0.00 0.12 0.16 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-22 129 10 -29.2252 -101.48098 120.6 18.378 35.371 0.00 0.13 0.14 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-22 129 7 -29.2252 -101.48098 159.4 17.286 35.167 1.31 0.23 0.12 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-23 133 19 -30.042 -98.39228 19.8 19.768 35.457 0.05 0.14 0.13 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-23 133 16 -30.042 -98.39228 45.3 18.677 35.341 0.00 0.13 0.14 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-23 133 14 -30.042 -98.39228 59.3 18.881 35.458 0.00 0.13 0.15 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-23 133 12 -30.042 -98.39228 85.1 18.74 35.462 0.00 0.13 0.14 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-23 133 10 -30.042 -98.39228 110 18.61 35.444 0.00 0.13 0.14 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-23 133 7 -30.042 -98.39228 149.7 18.378 35.395 0.05 0.15 0.15 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-24 137 19 -30.78638 -95.4272 15 18.02 34.858 0.00 0.15 0.17 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-24 137 16 -30.78638 -95.4272 34.9 18.04 34.86 0.00 0.15 0.16 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-24 137 14 -30.78638 -95.4272 49.7 17.609 34.828 0.00 0.15 0.17 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-24 137 12 -30.78638 -95.4272 69.2 17.157 34.866 0.00 0.15 0.16 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-24 137 10 -30.78638 -95.4272 99.7 16.951 34.894 0.15 0.16 0.16 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-24 137 7 -30.78638 -95.4272 119.5 16.923 34.916 0.39 0.20 0.16 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-28 162 21 -31.869 -91.41518 4.8 18.2178 34.6901 nd 0.19 0.21 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-28 162 19 -31.869 -91.41518 15.1 18.0481 34.6903 nd 0.22 0.19 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-28 162 16 -31.869 -91.41518 29.8 17.987 34.6865 nd 0.19 0.22 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-28 162 14 -31.869 -91.41518 40 17.0367 34.6049 nd 0.19 0.23 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-28 162 12 -31.869 -91.41518 60.4 16.5443 34.6732 nd 0.21 0.21 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-28 162 10 -31.869 -91.41518 78.2 16.2068 34.6223 nd 0.24 0.21 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-28 162 7 -31.869 -91.41518 99.4 16.0308 34.6164 nd 0.31 0.21 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-28 162 5 -31.869 -91.41518 110.6 15.906 34.5944 nd 0.31 0.20 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-28 162 4 -31.869 -91.41518 125.1 15.6364 34.5412 nd 0.30 0.21 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-28 162 3 -31.869 -91.41518 149.6 15.3149 34.4724 nd 0.36 0.16 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-28 162 2 -31.869 -91.41518 189.4 14.5498 34.3375 nd 0.46 0.16 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-28 162 1 -31.869 -91.41518 249.9 11.5617 34.2521 nd 1.00 0.15 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-30 176 3 -31.91738 -91.40722 303.7 9.96 34.2079 nd 1.30 0.10 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-30 176 9 -31.91738 -91.40722 401.5 7.4869 34.3241 nd 2.07 0.06 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-30 176 11 -31.91738 -91.40722 600.8 5.711 34.2776 nd 1.89 0.07 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-30 176 12 -31.91738 -91.40722 800.5 4.7847 34.2718 nd 2.16 0.07 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-30 176 13 -31.91738 -91.40722 1001.4 3.8903 34.364 nd 2.58 0.07 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-30 176 15 -31.91738 -91.40722 2001.1 2.1899 34.631 nd 2.61 0.09 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-01 178 19 -32.39545 -86.78242 14.8 17.3278 34.353 0.05 0.31 0.22 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-01 178 16 -32.39545 -86.78242 30 17.1962 34.3562 2.28 0.32 0.24 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-01 178 14 -32.39545 -86.78242 40.6 16.1555 34.3047 2.33 0.34 0.22 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-01 178 12 -32.39545 -86.78242 53.3 15.2465 34.2622 3.06 0.39 0.19 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-01 178 10 -32.39545 -86.78242 70.1 14.9522 34.3008 nd 0.37 0.18 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-01 178 7 -32.39545 -86.78242 95.5 14.7349 34.2853 2.91 0.41 0.16 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-02 182 19 -32.68325 -84.0737 14.7 17.4407 34.2435 3.64 0.39 0.21 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-02 182 16 -32.68325 -84.0737 30 16.4748 34.2111 3.08 0.35 0.23 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-02 182 14 -32.68325 -84.0737 40 15.4507 34.1856 3.64 0.37 0.22 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-02 182 12 -32.68325 -84.0737 59.7 14.8119 34.2245 3.96 0.45 0.17 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-02 182 10 -32.68325 -84.0737 80.2 14.5688 34.2093 4.81 0.52 0.13 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-02 182 7 -32.68325 -84.0737 99.3 13.9043 34.1051 6.22 0.56 0.10 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-03 186 19 -33.02312 -81.20049 14.2 17.2028 34.2707 2.77 0.37 0.22 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-03 186 16 -33.02312 -81.20049 35.4 16.578 34.2861 2.72 0.38 0.20 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-03 186 14 -33.02312 -81.20049 49.9 16.1802 34.2571 2.67 0.37 0.21 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-03 186 12 -33.02312 -81.20049 70.4 15.108 34.2019 3.30 0.38 0.22 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-03 186 10 -33.02312 -81.20049 90.5 14.6581 34.2009 4.32 0.48 0.19 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-03 186 7 -33.02312 -81.20049 116.4 14.1259 34.1446 5.97 0.56 0.15 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-04 190 21 -33.354 -78.11878 4.7 17.5647 33.947 0.10 0.27 0.26 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-04 190 18 -33.354 -78.11878 14.1 16.1316 33.9486 0.24 0.28 0.24 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-04 190 16 -33.354 -78.11878 20.3 15.8947 33.9434 0.73 0.31 0.23 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-04 190 14 -33.354 -78.11878 30 15.3185 34.0051 2.33 0.36 0.33 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-04 190 12 -33.354 -78.11878 41.1 14.813 33.9936 3.30 0.43 0.25 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-04 190 9 -33.354 -78.11878 50.6 13.8693 33.9535 4.61 0.58 0.16 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-05 194 21 -33.60613 -75.83113 5.6 16.8075 34.0462 0.07 0.36 0.28 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-05 194 18 -33.60613 -75.83113 14.7 16.7961 34.0458 0.07 0.36 0.28 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-05 194 16 -33.60613 -75.83113 20.4 16.7886 34.0448 0.07 0.36 0.26 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-05 194 14 -33.60613 -75.83113 29.7 16.2083 34.0331 0.05 0.35 0.52 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-05 194 12 -33.60613 -75.83113 39.5 15.7484 34.0473 0.14 0.36 0.31 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-05 194 9 -33.60613 -75.83113 50.2 15.0761 34.0504 1.63 0.53 0.22 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-07 204 21 -33.9332 -73.36405 5 15.9309 34.2456 0.29 0.51 0.44 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-07 204 18 -33.9332 -73.36405 9 15.9306 34.2456 0.29 0.57 0.42 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-07 204 16 -33.9332 -73.36405 15.4 15.9307 34.2457 nd 0.52 0.43 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-07 204 14 -33.9332 -73.36405 19.6 15.9158 34.2453 0.68 0.55 0.43 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-07 204 12 -33.9332 -73.36405 24.8 15.918 34.2434 nd 0.61 0.46 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-07 204 9 -33.9332 -73.36405 35.7 13.9263 34.2717 nd 0.67 0.38 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE nd 213 21 -34.51367 -72.41662 4.4 nd nd nd 1.62 0.38 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE nd 213 18 -34.51367 -72.41662 10 nd nd nd 1.72 0.37 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE nd 213 16 -34.51367 -72.41662 15.1 nd nd nd 1.81 0.29 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE nd 213 14 -34.51367 -72.41662 19.8 nd nd nd 1.84 0.33 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE nd 213 12 -34.51367 -72.41662 30.2 nd nd nd 2.02 0.25 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE nd 213 9 -34.51367 -72.41662 39.7 nd nd nd 2.11 0.24 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-14 104 21 -26.05263 -114.01095 5.1 22.408 36.021 0.00 0.12 0.18 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-14 104 19 -26.05263 -114.01095 18.4 22.292 36.028 0.00 0.13 0.16 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-14 104 16 -26.05263 -114.01095 50.4 22.108 36.046 0.00 0.13 0.17 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-14 104 13 -26.05263 -114.01095 71.3 21.906 36.022 0.00 0.12 0.17 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-14 104 12 -26.05263 -114.01095 89.5 21.427 35.976 0.00 0.12 0.17 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-14 104 10 -26.05263 -114.01095 118.8 20.76 35.845 0.00 0.13 0.16 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-14 104 8 -26.05263 -114.01095 140.3 20.235 35.74 0.00 0.13 0.16 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-14 104 7 -26.05263 -114.01095 158.9 19.711 35.634 0.00 0.17 0.13 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-14 104 5 -26.05263 -114.01095 181.1 18.658 35.438 0.49 0.21 0.14 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-14 104 4 -26.05263 -114.01095 199.5 17.851 35.312 1.75 0.29 0.12 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-14 104 3 -26.05263 -114.01095 228.6 16.806 35.144 3.45 0.39 0.10 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-14 104 2 -26.05263 -114.01095 270.7 14.858 34.858 5.78 0.55 0.27 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-16 118 24 -26.07065 -114.0013 302.6 13.392 34.716 nd 0.72 0.08 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-16 118 23 -26.07065 -114.0013 403.4 9.079 34.391 nd 1.47 0.04 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-16 118 22 -26.07065 -114.0013 600 6.093 34.31 nd 1.84 0.05 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-16 118 21 -26.07065 -114.0013 800.9 4.983 34.298 nd 2.19 0.06 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-16 118 20 -26.07065 -114.0013 1000.4 4.099 34.401 nd 2.57 0.07 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-11-16 118 19 -26.07065 -114.0013 2001.5 2.06 34.64 nd 2.57 0.07 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-06 198 21 -33.99632 -73.36961 5.2 15.7198 34.241 nd 0.56 0.36 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-06 198 18 -33.99632 -73.36961 10.1 15.726 34.2411 nd 0.56 0.34 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-06 198 16 -33.99632 -73.36961 14.8 15.7066 34.2398 nd 0.59 0.49 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-06 198 15 -33.99632 -73.36961 20 15.647 34.2366 nd 0.70 0.40 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-06 198 14 -33.99632 -73.36961 25 15.5861 34.2323 nd 0.89 0.35 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-06 198 12 -33.99632 -73.36961 29.9 14.2374 34.2538 nd 1.77 0.46 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-06 198 11 -33.99632 -73.36961 35.4 12.5 34.3388 nd 2.11 0.30 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-06 198 9 -33.99632 -73.36961 40.2 12.2614 34.34 nd 2.15 0.27 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-06 198 7 -33.99632 -73.36961 45.3 11.9656 34.3743 nd 2.33 0.28 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-06 198 6 -33.99632 -73.36961 49.9 11.6311 34.3525 nd 2.31 0.16 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-06 198 5 -33.99632 -73.36961 75.4 11.0336 34.3805 nd 2.51 0.17 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-06 198 4 -33.99632 -73.36961 100.7 10.8903 34.4941 nd 2.73 0.12 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-08 210 12 -33.8605 -73.34022 148.6 10.1481 34.5037 nd 2.66 0.23 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-08 210 10 -33.8605 -73.34022 200.4 9.524 34.521 nd 2.77 0.27 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-08 210 8 -33.8605 -73.34022 250.3 9.0263 34.5245 nd 2.86 0.20 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-08 210 6 -33.8605 -73.34022 301 8.3728 34.4905 nd 2.84 0.14 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-08 210 4 -33.8605 -73.34022 399.9 7.1448 34.4149 nd 2.41 0.28 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd BIOSOPE 2004-12-08 210 2 -33.8605 -73.34022 503.4 6.1605 34.3557 nd 2.63 0.13 2 South Pacific Wet oxidation Raimbault; P.; Garcia; N.; and Cerutti; F.: Distribution of inorganic and organic nutrients in the South Pacific Ocean evidence for long-term accumulation of organic matter in nitrogen-depleted waters; Biogeosciences; 5; 281 298; https://doi.org/10.5194/bg-5-281-2008; 2008 nd OUTPACE 2015-02-22 out_c_006 2 -17.9418 159.9255 149.612 21.1097 35.6954 3.17 0.30 0.10 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-22 out_c_006 3 -17.9418 159.9255 124.97 21.6266 35.701 2.84 0.28 0.11 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-22 out_c_006 6 -17.9418 159.9255 104.741 22.2953 35.6949 1.54 0.20 0.12 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-22 out_c_006 9 -17.9418 159.9255 71.201 24.2831 35.5917 0.00 0.11 0.15 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-22 out_c_006 11 -17.9418 159.9255 54.034 26.108 35.3997 0.02 0.08 0.14 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-22 out_c_006 13 -17.9418 159.9255 36.026 28.1106 35.1108 0.01 0.02 0.18 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-22 out_c_006 15 -17.9418 159.9255 24.133 28.2469 35.0871 0.00 0.06 0.19 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-22 out_c_006 18 -17.9418 159.9255 16.624 28.3636 35.083 0.00 0.00 0.30 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-22 out_c_006 19 -17.9418 159.9255 9.869 29.0101 35.0684 0.00 0.04 0.17 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-22 out_c_006 23 -17.9418 159.9255 5.674 29.1668 35.0605 0.01 0.03 0.17 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-23 out_c_010 1 -18.6078 162.1248 199.39 21.19 35.7321 5.38 0.47 0.08 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-23 out_c_010 2 -18.6078 162.1248 150.278 22.437 35.6937 3.71 0.34 0.10 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-23 out_c_010 3 -18.6078 162.1248 124.977 22.9537 35.6891 2.80 0.31 0.11 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-23 out_c_010 6 -18.6078 162.1248 105.362 23.4386 35.6361 1.85 0.26 0.09 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-23 out_c_010 7 -18.6078 162.1248 88.2 24.105 35.6005 0.77 0.19 0.12 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-23 out_c_010 9 -18.6078 162.1248 70.228 24.8337 35.5396 0.02 0.13 0.14 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-23 out_c_010 11 -18.6078 162.1248 53.239 25.6637 35.4598 0.05 0.09 0.16 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-23 out_c_010 19 -18.6078 162.1248 9.532 28.8666 35.1928 0.00 0.03 0.18 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-23 out_c_010 23 -18.6078 162.1248 5.156 28.7881 35.1893 0.02 0.03 0.19 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-24 out_c_019 2 -19.4955 165.0093 150.423 23.1483 35.723 3.96 0.36 0.10 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-24 out_c_019 3 -19.4955 165.0093 125.914 24.0126 35.6618 2.20 0.30 0.10 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-24 out_c_019 6 -19.4955 165.0093 105.281 24.4989 35.5594 0.77 0.20 0.12 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-24 out_c_019 7 -19.4955 165.0093 88.519 24.9601 35.5193 0.53 0.18 0.13 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-24 out_c_019 9 -19.4955 165.0093 71.304 25.6016 35.4301 0.03 0.15 0.11 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-24 out_c_019 11 -19.4955 165.0093 54.427 26.5235 35.3327 0.00 0.09 0.17 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-24 out_c_019 13 -19.4955 165.0093 36.312 27.2729 35.2424 0.04 0.06 0.18 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-24 out_c_019 15 -19.4955 165.0093 25.55 28.6367 34.9615 0.02 0.02 0.18 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-24 out_c_019 18 -19.4955 165.0093 16.584 28.8649 34.8805 0.03 0.01 0.19 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-24 out_c_019 19 -19.4955 165.0093 9.307 29.0252 34.8698 0.04 0.01 0.18 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-24 out_c_019 23 -19.4955 165.0093 5.867 29.0497 34.8703 0.04 0.00 0.18 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-24 out_c_020 18 -19.4907 165.0082 399.801 14.1636 35.1108 12.44 0.91 0.02 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-24 out_c_020 19 -19.4907 165.0082 300.448 18.4446 35.5233 6.42 0.52 0.04 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-24 out_c_020 20 -19.4907 165.0082 250.75 20.1137 35.6471 6.20 0.48 0.05 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-24 out_c_020 23 -19.4907 165.0082 201.534 21.6462 35.7286 5.90 0.43 0.07 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-26 out_c_027 1 -19.2248 164.6495 498.685 10.0638 34.7033 19.35 1.39 0.02 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-26 out_c_027 2 -19.2248 164.6495 397.374 13.8547 35.0991 12.45 0.92 0.02 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-26 out_c_027 3 -19.2248 164.6495 301.335 17.6994 35.4372 8.53 0.73 0.03 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-26 out_c_027 4 -19.2248 164.6495 201.723 21.9705 35.7195 4.32 0.40 0.07 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-26 out_c_027 5 -19.2248 164.6495 151.621 23.7621 35.6817 2.49 0.33 0.08 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-26 out_c_027 7 -19.2248 164.6495 101.88 24.7562 35.549 0.87 0.22 0.10 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-26 out_c_027 9 -19.2248 164.6495 88.455 25.1377 35.4966 0.60 0.18 0.12 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-26 out_c_027 11 -19.2248 164.6495 70.614 25.6466 35.4305 0.11 0.13 0.15 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-26 out_c_027 13 -19.2248 164.6495 53.546 26.3693 35.3512 0.00 0.10 0.17 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-26 out_c_027 15 -19.2248 164.6495 35.433 28.6084 35.0282 0.01 0.02 0.19 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-26 out_c_027 17 -19.2248 164.6495 24.525 28.8869 34.9671 0.04 0.02 0.17 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-26 out_c_027 21 -19.2248 164.6495 9.353 29.0802 34.7613 0.02 0.00 0.20 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-02-26 out_c_027 23 -19.2248 164.6495 5.246 29.1519 34.729 0.04 0.01 0.17 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-02 out_c_066 1 -19.2242 164.5877 200.313 21.7826 35.76 4.95 0.47 0.06 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-02 out_c_066 2 -19.2242 164.5877 150.328 23.1248 35.6841 3.07 0.35 0.07 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-02 out_c_066 3 -19.2242 164.5877 125.297 23.7495 35.6472 2.32 0.30 0.08 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-02 out_c_066 6 -19.2242 164.5877 105.935 24.1396 35.6123 1.84 0.28 0.07 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-02 out_c_066 7 -19.2242 164.5877 88.384 24.8467 35.542 0.92 0.24 0.09 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-02 out_c_066 9 -19.2242 164.5877 70.699 25.335 35.4755 0.02 0.18 0.10 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-02 out_c_066 11 -19.2242 164.5877 54.042 25.8532 35.4102 0.00 0.17 0.10 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-02 out_c_066 13 -19.2242 164.5877 35.199 26.7792 35.315 0.00 0.13 0.12 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-02 out_c_066 15 -19.2242 164.5877 23.849 27.9162 35.1543 0.00 0.06 0.16 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-02 out_c_066 23 -19.2242 164.5877 5.571 29.7346 34.9416 0.02 0.03 0.12 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-02 out_c_067 20 -19.2233 164.5787 250.608 20.2184 35.7055 7.23 0.63 0.04 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-02 out_c_067 24 -19.2233 164.5787 200.079 22.2707 35.7364 4.72 0.43 0.05 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-04 out_c_070 2 -19.9832 168.0118 151.045 20.937 35.691 2.55 0.22 0.09 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-04 out_c_070 3 -19.9832 168.0118 126.501 21.5116 35.6935 1.44 0.18 0.09 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-04 out_c_070 6 -19.9832 168.0118 105.855 21.783 35.6978 1.27 0.16 0.11 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-04 out_c_070 7 -19.9832 168.0118 88.882 22.3304 35.6987 1.15 0.15 0.11 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-04 out_c_070 11 -19.9832 168.0118 53.776 24.0523 35.668 0.01 0.06 0.14 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-04 out_c_070 13 -19.9832 168.0118 35.421 25.8663 35.6501 0.00 0.04 0.14 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-04 out_c_070 15 -19.9832 168.0118 24.702 27.7499 35.3656 0.00 0.03 0.13 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-04 out_c_070 18 -19.9832 168.0118 16.393 28.5439 35.3564 0.00 0.03 0.14 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-04 out_c_070 19 -19.9832 168.0118 9.559 28.7332 35.3627 0.00 0.05 0.14 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-04 out_c_070 23 -19.9832 168.0118 5.22 28.7346 35.363 0.01 0.06 0.15 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-04 out_c_071 17 -19.98 168.0157 499.394 9.3131 34.6711 20.00 1.40 0.02 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-04 out_c_071 19 -19.98 168.0157 300.722 16.0504 35.3514 8.38 0.67 0.02 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-04 out_c_071 20 -19.98 168.0157 249.251 18.3246 35.5894 4.65 0.39 0.05 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-04 out_c_071 24 -19.98 168.0157 199.244 19.7116 35.6617 3.29 0.28 0.09 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-05 out_c_074 1 -22.0002 169.9943 201.308 19.9059 35.6543 4.08 0.33 0.13 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-05 out_c_074 2 -22.0002 169.9943 150.638 21.0615 35.6963 2.18 0.20 0.10 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-05 out_c_074 6 -22.0002 169.9943 105.517 21.9409 35.704 1.15 0.16 0.12 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-05 out_c_074 9 -22.0002 169.9943 71.977 23.1991 35.6721 1.34 0.21 0.08 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-05 out_c_074 11 -22.0002 169.9943 53.927 24.9936 35.5573 0.14 0.09 0.14 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-05 out_c_074 13 -22.0002 169.9943 35.681 26.5018 35.4286 0.01 0.03 0.16 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-05 out_c_074 15 -22.0002 169.9943 24.513 27.4658 35.3497 0.01 0.08 0.16 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-05 out_c_074 18 -22.0002 169.9943 14.794 29.1201 35.041 0.01 0.03 0.14 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-05 out_c_074 19 -22.0002 169.9943 9.231 29.5253 34.8793 0.01 0.04 0.16 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-05 out_c_074 23 -22.0002 169.9943 4.536 29.5124 34.9081 0.00 0.04 0.14 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-05 out_c_075 17 -21.9997 169.9965 500.478 10.7505 34.7908 17.56 1.24 0.05 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-05 out_c_075 18 -21.9997 169.9965 400.579 13.4786 35.0155 13.58 1.03 0.07 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-05 out_c_075 19 -21.9997 169.9965 301.476 17.2649 35.4654 6.65 0.52 0.12 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-05 out_c_075 20 -21.9997 169.9965 250.999 18.9462 35.5835 4.93 0.41 0.07 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-05 out_c_075 24 -21.9997 169.9965 200.413 19.981 35.6633 3.66 0.31 0.07 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-06 out_c_078 1 -21.3732 172.1198 200.244 21.4935 35.723 3.71 0.33 0.07 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-06 out_c_078 2 -21.3732 172.1198 150.474 22.9121 35.7016 1.92 0.22 0.10 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-06 out_c_078 3 -21.3732 172.1198 135.713 23.4521 35.6961 0.95 0.19 0.10 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-06 out_c_078 6 -21.3732 172.1198 119.568 23.9103 35.6763 0.25 0.14 0.12 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-06 out_c_078 7 -21.3732 172.1198 100.854 24.3012 35.671 0.06 0.12 0.13 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-06 out_c_078 11 -21.3732 172.1198 60.128 26.0567 35.6228 0.03 0.03 0.19 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-06 out_c_078 13 -21.3732 172.1198 40.762 27.9061 35.3923 0.04 0.04 0.17 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-06 out_c_078 15 -21.3732 172.1198 28.196 28.6292 35.062 0.02 0.04 0.17 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-06 out_c_078 18 -21.3732 172.1198 18.222 29.2885 35.0298 0.03 0.03 0.19 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-06 out_c_078 19 -21.3732 172.1198 11.144 29.5601 34.916 0.02 0.03 0.17 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-06 out_c_078 23 -21.3732 172.1198 5.277 29.5789 34.8974 0.01 0.01 0.21 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-06 out_c_079 19 -21.3758 172.1193 300.323 18.3841 35.5233 5.83 0.47 0.06 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-06 out_c_079 20 -21.3758 172.1193 250.223 19.9928 35.6532 4.31 0.37 0.06 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-06 out_c_079 24 -21.3758 172.1193 200.495 21.2807 35.7148 4.00 0.35 0.08 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-07 out_c_082 2 -20.7697 174.25 174.107 21.0716 35.6822 3.40 0.26 0.09 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-07 out_c_082 3 -20.7697 174.25 149.591 21.7706 35.6859 2.96 0.25 0.08 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-07 out_c_082 6 -20.7697 174.25 134.802 21.9997 35.6749 2.25 0.21 0.10 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-07 out_c_082 7 -20.7697 174.25 114.789 22.582 35.6722 1.80 0.19 0.13 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-07 out_c_082 9 -20.7697 174.25 90.043 23.4817 35.6655 0.43 0.13 0.13 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-07 out_c_082 11 -20.7697 174.25 69.994 24.5541 35.6398 0.09 0.10 0.13 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-07 out_c_082 13 -20.7697 174.25 44.595 27.1876 35.4954 0.02 0.02 0.18 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-07 out_c_082 15 -20.7697 174.25 32.058 27.9005 35.4931 0.02 0.02 0.17 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-07 out_c_082 18 -20.7697 174.25 20.85 28.1977 35.3869 0.01 0.02 0.21 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-07 out_c_082 19 -20.7697 174.25 12.247 29.6206 35.0084 0.02 0.04 0.18 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-07 out_c_082 23 -20.7697 174.25 5.579 29.9017 35.0171 0.00 0.04 0.21 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-09 out_c_091 19 -20.9963 178.6087 300.431 16.8371 35.4182 6.93 0.55 0.04 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-09 out_c_091 20 -20.9963 178.6087 250.549 18.5004 35.5717 4.71 0.40 0.04 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-09 out_c_091 24 -20.9963 178.6087 200.003 19.6061 35.6521 3.58 0.30 0.05 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-10 out_c_094 2 -20.4417 -178.5105 175.482 21.3639 35.6715 2.58 0.26 0.05 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-10 out_c_094 3 -20.4417 -178.5105 150.782 22.0512 35.6751 2.48 0.24 0.05 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-10 out_c_094 6 -20.4417 -178.5105 134.919 22.401 35.659 1.45 0.19 0.06 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-10 out_c_094 7 -20.4417 -178.5105 114.486 23.0034 35.6546 0.32 0.14 0.08 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-10 out_c_094 9 -20.4417 -178.5105 90.177 23.8338 35.6631 0.02 0.09 0.11 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-10 out_c_094 11 -20.4417 -178.5105 69.23 24.6423 35.6497 0.03 0.09 0.12 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-10 out_c_094 13 -20.4417 -178.5105 45.274 26.5594 35.5484 0.04 0.07 0.13 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-10 out_c_094 15 -20.4417 -178.5105 33.108 28.0026 35.3435 0.01 0.02 0.16 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-10 out_c_094 18 -20.4417 -178.5105 21.738 29.4012 35.2132 0.01 0.01 0.16 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-10 out_c_094 19 -20.4417 -178.5105 12.988 29.5315 35.2097 0.01 0.01 0.16 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-10 out_c_094 23 -20.4417 -178.5105 5.765 29.6064 35.2114 0.01 0.01 0.17 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-10 out_c_095 24 -20.44 -178.5105 201.656 21.0113 35.6709 3.14 0.29 0.04 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-11 out_c_098 1 -20.0028 -175.6542 200.655 19.5649 35.61 3.54 0.33 0.06 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-11 out_c_098 3 -20.0028 -175.6542 151.548 20.7522 35.6633 2.75 0.26 0.07 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-11 out_c_098 6 -20.0028 -175.6542 135.72 21.3419 35.6841 2.42 0.26 0.06 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-11 out_c_098 7 -20.0028 -175.6542 114.375 22.1146 35.6777 2.29 0.22 0.06 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-11 out_c_098 9 -20.0028 -175.6542 90.083 22.8714 35.6798 0.05 0.14 0.08 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-11 out_c_098 11 -20.0028 -175.6542 70.779 23.7673 35.678 0.02 0.08 0.12 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-11 out_c_098 13 -20.0028 -175.6542 45.479 26.2259 35.5802 0.00 0.04 0.14 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-11 out_c_098 15 -20.0028 -175.6542 32.586 27.0351 35.5117 0.01 0.02 0.16 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-11 out_c_098 18 -20.0028 -175.6542 21.675 27.5472 35.4813 0.02 0.05 0.12 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-11 out_c_098 19 -20.0028 -175.6542 12.071 28.8867 35.4173 0.01 0.02 0.15 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-11 out_c_098 23 -20.0028 -175.6542 5.859 29.186 35.4111 0.02 0.02 0.15 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-11 out_c_099 19 -20.0057 -175.6475 297.671 15.8426 35.2641 8.13 0.64 0.05 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-11 out_c_099 20 -20.0057 -175.6475 251.052 17.9689 35.4858 5.16 0.43 0.04 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-12 out_c_102 1 -19.5237 -172.7885 199.819 20.0378 35.6254 2.58 0.21 0.08 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-12 out_c_102 2 -19.5237 -172.7885 176.144 20.4695 35.6191 1.79 0.21 0.06 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-12 out_c_102 3 -19.5237 -172.7885 150.828 21.1151 35.6802 2.14 0.26 0.05 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-12 out_c_102 6 -19.5237 -172.7885 128.237 22.0573 35.6961 2.49 0.27 0.06 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-12 out_c_102 7 -19.5237 -172.7885 107.803 22.9046 35.7075 1.45 0.21 0.09 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-12 out_c_102 9 -19.5237 -172.7885 84.702 24.0045 35.7257 0.01 0.13 0.10 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-12 out_c_102 11 -19.5237 -172.7885 65.499 25.2848 35.7064 0.01 0.10 0.14 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-12 out_c_102 13 -19.5237 -172.7885 43.298 26.9282 35.5955 0.01 0.06 0.16 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-12 out_c_102 15 -19.5237 -172.7885 30.363 28.897 35.1336 0.02 0.06 0.15 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-12 out_c_102 18 -19.5237 -172.7885 19.214 29.4943 34.9667 0.05 0.06 0.16 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-12 out_c_102 19 -19.5237 -172.7885 10.713 29.8033 34.8934 0.00 0.08 0.16 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-12 out_c_102 23 -19.5237 -172.7885 5.749 29.8378 34.8955 0.04 0.08 0.15 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-12 out_c_103 18 -19.5368 -172.7813 398.84 13.0843 35.028 12.23 0.89 0.02 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-12 out_c_103 19 -19.5368 -172.7813 299.852 17.1736 35.4628 4.14 0.36 0.06 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-12 out_c_103 20 -19.5368 -172.7813 251.183 18.509 35.5306 4.23 0.35 0.05 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-12 out_c_103 24 -19.5368 -172.7813 199.781 20.1418 35.6274 2.23 0.22 0.06 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-15 out_c_109 3 -18.2462 -170.8275 299.423 16.5467 35.2847 7.63 0.65 0.03 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-15 out_c_109 4 -18.2462 -170.8275 201.193 21.1541 35.79 3.27 0.35 0.06 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-15 out_c_109 5 -18.2462 -170.8275 149.422 22.2933 35.7545 2.33 0.27 0.09 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-15 out_c_109 9 -18.2462 -170.8275 69.187 25.2403 35.7155 0.10 0.11 0.14 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-15 out_c_109 11 -18.2462 -170.8275 55.913 26.165 35.6565 0.05 0.11 0.16 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-15 out_c_109 13 -18.2462 -170.8275 42.428 27.0212 35.5692 0.04 0.07 0.18 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-15 out_c_109 15 -18.2462 -170.8275 27.399 29.2191 35.25 0.01 0.04 0.18 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-15 out_c_109 19 -18.2462 -170.8275 11.932 29.9674 35.0821 0.03 0.01 0.18 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-15 out_c_109 23 -18.2462 -170.8275 5.589 30.1582 35.0823 nd 0.01 0.17 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-20 out_c_150 2 -18.179 -170.7433 152.048 22.5548 35.7511 1.53 0.24 0.12 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-20 out_c_150 3 -18.179 -170.7433 125.479 23.5083 35.7499 0.56 0.14 0.15 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-20 out_c_150 6 -18.179 -170.7433 83.501 25.0636 35.7323 0.01 0.13 0.13 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-20 out_c_150 7 -18.179 -170.7433 69.165 25.7374 35.6852 0.04 0.11 0.16 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-20 out_c_150 9 -18.179 -170.7433 56.784 26.2317 35.6751 0.03 0.12 0.16 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-20 out_c_150 11 -18.179 -170.7433 41.743 27.1323 35.5734 0.02 0.08 0.16 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-20 out_c_150 13 -18.179 -170.7433 26.734 29.657 35.1263 0.02 0.04 0.16 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-20 out_c_150 15 -18.179 -170.7433 19.3 29.9321 35.052 0.00 0.02 0.17 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-20 out_c_150 18 -18.179 -170.7433 12.192 29.9305 35.052 0.00 0.02 0.17 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-20 out_c_150 19 -18.179 -170.7433 6.832 29.9301 35.0521 0.01 0.03 0.18 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-20 out_c_150 23 -18.179 -170.7433 5.536 29.9213 35.0404 0.04 0.04 0.17 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-20 out_c_151 19 -18.1745 -170.7385 296.94 17.3588 35.3801 6.13 0.54 0.01 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-20 out_c_151 20 -18.1745 -170.7385 249.471 19.6111 35.6375 4.72 0.44 0.04 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-20 out_c_151 24 -18.1745 -170.7385 203.571 21.1383 35.8012 3.82 0.39 0.04 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-21 out_c_152 1 -18.2007 -169.0728 500.745 8.3926 34.4702 23.60 1.67 0.02 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-21 out_c_152 2 -18.2007 -169.0728 400.327 11.7201 34.7873 15.26 1.09 0.02 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-21 out_c_152 3 -18.2007 -169.0728 300.133 16.2255 35.2339 8.14 0.69 0.05 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-21 out_c_152 4 -18.2007 -169.0728 201.756 20.6276 35.7976 4.05 0.43 0.07 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-21 out_c_152 5 -18.2007 -169.0728 150.41 22.5011 35.9628 2.17 0.33 0.08 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-21 out_c_152 7 -18.2007 -169.0728 100.557 23.9781 35.8336 0.17 0.16 0.13 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-21 out_c_152 9 -18.2007 -169.0728 75.644 25.1626 35.7859 0.01 0.16 0.14 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-21 out_c_152 11 -18.2007 -169.0728 64.877 25.8702 35.7322 0.02 0.14 0.17 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-21 out_c_152 13 -18.2007 -169.0728 55.238 26.5672 35.6835 0.01 0.14 0.16 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-21 out_c_152 15 -18.2007 -169.0728 45.061 27.1103 35.64 0.01 0.14 0.17 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-21 out_c_152 19 -18.2007 -169.0728 25.372 29.5928 35.092 0.01 0.15 0.16 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-21 out_c_152 23 -18.2007 -169.0728 5.121 29.5913 35.0912 0.00 0.13 0.19 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-23 out_c_158 3 -18.4307 -165.916 300.473 16.6876 35.2856 9.31 0.84 0.01 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-23 out_c_158 4 -18.4307 -165.916 250.333 19.096 35.6115 5.33 0.54 0.03 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-23 out_c_158 5 -18.4307 -165.916 200.136 20.6863 35.7901 3.57 0.40 0.05 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-23 out_c_158 7 -18.4307 -165.916 151.482 21.9888 35.8632 2.22 0.33 0.04 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-23 out_c_158 9 -18.4307 -165.916 135.556 22.5416 35.8842 1.09 0.27 0.08 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-23 out_c_158 11 -18.4307 -165.916 120.897 22.9518 35.8358 0.03 0.19 0.13 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-23 out_c_158 13 -18.4307 -165.916 92.261 24.0959 35.7425 0.03 0.13 0.15 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-23 out_c_158 15 -18.4307 -165.916 60.245 25.8864 35.7067 0.05 0.13 0.13 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-23 out_c_158 19 -18.4307 -165.916 27.203 29.1759 35.2162 0.02 0.16 0.15 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-23 out_c_158 23 -18.4307 -165.916 6.641 29.3923 35.2119 0.02 0.28 0.15 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-24 out_c_163 17 -18.4282 -165.9315 300.778 16.5252 35.2632 9.39 0.85 0.03 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-24 out_c_163 18 -18.4282 -165.9315 201.358 20.441 35.7541 3.59 0.40 0.07 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-24 out_c_163 19 -18.4282 -165.9315 135.785 22.5385 35.8361 0.64 0.21 0.11 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-24 out_c_163 20 -18.4282 -165.9315 51.297 25.5336 35.7204 0.02 0.09 0.16 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-24 out_c_163 21 -18.4282 -165.9315 30.392 27.4317 35.5138 0.02 0.10 0.18 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-24 out_c_163 22 -18.4282 -165.9315 20.518 29.1495 35.24 0.01 0.14 0.19 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-24 out_c_163 23 -18.4282 -165.9315 10.765 29.3295 35.2115 0.01 0.16 0.17 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-24 out_c_163 24 -18.4282 -165.9315 4.536 29.33 35.2112 0.02 0.16 0.16 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-28 out_c_194 6 -18.4952 -165.8647 24.93 29.0887 35.2838 nd nd 0.30 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-28 out_c_194 7 -18.4952 -165.8647 24.884 29.0861 35.2853 nd nd 0.31 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-28 out_c_194 8 -18.4952 -165.8647 24.65 29.0859 35.2851 nd nd 0.31 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-28 out_c_194 9 -18.4952 -165.8647 24.766 29.0914 35.2841 nd nd 0.34 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-28 out_c_194 10 -18.4952 -165.8647 25.007 29.1355 35.2781 nd nd 0.32 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-28 out_c_194 11 -18.4952 -165.8647 24.789 29.1446 35.2767 nd nd 0.31 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-28 out_c_194 12 -18.4952 -165.8647 24.919 29.151 35.2758 nd nd 0.32 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-28 out_c_194 13 -18.4952 -165.8647 24.715 29.1561 35.275 nd nd 0.32 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-28 out_c_194 14 -18.4952 -165.8647 24.957 29.171 35.272 nd nd 0.33 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-28 out_c_194 15 -18.4952 -165.8647 24.9 29.1723 35.2719 nd nd 0.31 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-28 out_c_198 1 -18.4912 -165.7915 297.703 17.446 35.3891 8.39 0.76 0.03 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-28 out_c_198 2 -18.4912 -165.7915 249.476 19.2293 35.6368 6.43 0.57 0.04 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-28 out_c_198 3 -18.4912 -165.7915 200.423 20.5635 35.79 4.02 0.44 0.03 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-28 out_c_198 5 -18.4912 -165.7915 177.151 21.5321 35.8984 3.30 0.39 0.07 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-28 out_c_198 6 -18.4912 -165.7915 150.217 22.3648 35.9228 1.79 0.30 0.07 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-28 out_c_198 7 -18.4912 -165.7915 135.77 22.6788 35.9188 0.98 0.26 0.09 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-28 out_c_198 8 -18.4912 -165.7915 119.977 22.995 35.8702 nd nd 0.12 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-28 out_c_198 11 -18.4912 -165.7915 91.416 23.9651 35.8364 0.03 0.14 0.14 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-28 out_c_198 13 -18.4912 -165.7915 60.733 26.0231 35.6996 0.04 0.11 0.15 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-28 out_c_198 15 -18.4912 -165.7915 42.233 27.5218 35.5054 0.04 0.11 0.17 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-28 out_c_198 18 -18.4912 -165.7915 27.279 29.1138 35.2593 0.03 0.13 0.20 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-28 out_c_198 19 -18.4912 -165.7915 17.216 29.1201 35.2572 0.02 0.14 0.18 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-28 out_c_198 23 -18.4912 -165.7915 7.256 29.1152 35.2573 0.01 0.14 0.17 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-28 out_c_199 18 -18.4842 -165.7792 400.514 12.1328 34.7933 14.94 1.12 0.03 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-28 out_c_199 19 -18.4842 -165.7792 299.662 16.7745 35.2969 9.33 0.81 0.04 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-28 out_c_199 20 -18.4842 -165.7792 249.952 18.976 35.6011 6.09 0.60 0.03 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-28 out_c_199 24 -18.4842 -165.7792 197.741 20.8194 35.8205 3.96 0.44 0.05 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-30 out_c_209 1 -18.395 -163.001 300.274 17.3308 35.3652 7.86 0.70 0.08 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-30 out_c_209 2 -18.395 -163.001 249.174 19.704 35.6867 5.28 0.51 0.08 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-30 out_c_209 3 -18.395 -163.001 199.327 21.6561 35.8918 3.30 0.39 0.12 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-30 out_c_209 6 -18.395 -163.001 165.23 22.4648 35.8405 0.76 0.23 0.13 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-30 out_c_209 7 -18.395 -163.001 139.975 23.4434 35.83 0.09 0.14 0.19 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-30 out_c_209 9 -18.395 -163.001 110.896 24.8161 35.8136 0.04 0.14 0.19 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-30 out_c_209 11 -18.395 -163.001 84.853 25.5853 35.7833 0.05 0.14 0.21 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-30 out_c_209 13 -18.395 -163.001 55.934 27.5651 35.6242 0.01 0.14 0.23 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-30 out_c_209 15 -18.395 -163.001 40.378 29.1064 35.0712 0.03 0.14 0.23 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-31 out_c_212 1 -18.265 -159.9913 300.275 17.9544 35.4622 7.88 0.74 0.05 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-31 out_c_212 2 -18.265 -159.9913 248.139 19.9578 35.7574 5.73 0.59 0.07 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-31 out_c_212 3 -18.265 -159.9913 198.698 22.1014 36.0304 4.16 0.47 0.10 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-31 out_c_212 6 -18.265 -159.9913 174.734 22.5011 36.0166 3.00 0.39 0.09 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-31 out_c_212 7 -18.265 -159.9913 148.103 23.5544 36.1056 2.62 0.40 0.11 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-31 out_c_212 9 -18.265 -159.9913 115.952 24.3329 35.9205 0.24 0.18 0.17 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-31 out_c_212 11 -18.265 -159.9913 88.08 25.5851 35.9202 0.03 0.17 0.19 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-31 out_c_212 13 -18.265 -159.9913 57.892 27.7516 35.7116 0.02 0.16 0.21 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-31 out_c_212 15 -18.265 -159.9913 41.565 29.1439 35.2885 0.01 0.17 0.21 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-31 out_c_212 18 -18.265 -159.9913 26.44 29.2301 35.2578 0.03 0.16 0.22 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd OUTPACE 2015-03-31 out_c_212 23 -18.265 -159.9913 5.482 29.2015 35.1762 0.01 0.17 0.20 2 South Pacific Wet oxidation Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological carbon pump in the western tropical South Pacific Ocean; Biogeosciences; 15; 2961 2989; https://doi.org/10.5194/bg-15-2961-2018; 2018. nd KH-11-10 2011-12-02 0 nd 30 145 0 nd nd 0.01 0.01 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-02 0 nd 30 145 50 23.78 34.79 0.01 0.00 0.16 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-02 0 nd 30 145 75 23.70 34.79 0.01 0.01 0.20 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-02 0 nd 30 145 100 19.27 34.78 0.24 0.05 0.20 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-02 0 nd 30 145 124 18.30 34.75 2.09 0.18 0.24 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-02 0 nd 30 145 150 17.72 34.72 3.63 0.20 0.42 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-05 1 nd 23 155 0 nd nd 0.02 0.03 0.11 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-05 1 nd 23 155 5 26.94 34.87 0.01 0.00 0.15 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-05 1 nd 23 155 8 26.93 34.87 0.01 0.00 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-05 1 nd 23 155 29 26.77 34.90 0.01 0.00 0.16 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-05 1 nd 23 155 49 26.32 35.06 0.01 0.00 0.11 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-05 1 nd 23 155 74 25.25 35.13 0.01 0.00 0.10 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-05 1 nd 23 155 99 22.07 35.03 0.01 0.01 0.11 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-05 1 nd 23 155 124 20.05 34.93 0.19 0.04 0.13 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-05 1 nd 23 155 134 19.61 34.89 0.15 0.04 0.09 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-05 1 nd 23 155 148 19.44 34.88 0.05 0.00 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-07 2 nd 23 160 0 nd nd 0.01 0.00 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-07 2 nd 23 160 6 26.81 34.91 0.01 0.00 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-07 2 nd 23 160 10 26.81 34.91 0.01 0.00 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-07 2 nd 23 160 19 26.81 34.91 0.01 0.00 0.24 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-07 2 nd 23 160 30 26.64 35.06 0.01 0.00 0.11 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-07 2 nd 23 160 51 26.39 35.14 0.01 0.00 0.11 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-07 2 nd 23 160 75 24.61 35.20 0.01 0.00 0.10 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-07 2 nd 23 160 99 21.11 35.04 0.01 0.02 0.11 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-07 2 nd 23 160 116 20.18 34.98 0.49 0.07 0.08 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-07 2 nd 23 160 149 19.29 34.89 1.07 0.09 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-08 3 nd 23 165 0 nd nd 0.01 0.03 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-08 3 nd 23 165 5 27.36 35.12 0.01 0.03 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-08 3 nd 23 165 9 27.36 35.12 0.01 0.04 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-08 3 nd 23 165 19 27.36 35.12 0.01 0.03 0.20 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-08 3 nd 23 165 30 27.36 35.12 0.01 0.03 0.15 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-08 3 nd 23 165 48 27.36 35.12 0.01 0.03 0.15 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-08 3 nd 23 165 97 25.54 35.35 0.01 0.03 0.23 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-08 3 nd 23 165 119 24.14 35.35 0.01 0.03 0.13 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-08 3 nd 23 165 148 22.07 35.25 1.14 0.12 0.20 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-10 4 nd 23 170 0 nd nd 0.01 0.01 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-10 4 nd 23 170 5 26.24 35.28 0.01 0.01 0.16 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-10 4 nd 23 170 10 26.24 35.28 0.01 0.01 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-10 4 nd 23 170 20 26.24 35.28 0.01 0.01 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-10 4 nd 23 170 31 26.25 35.29 0.01 0.01 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-10 4 nd 23 170 50 26.18 35.36 0.01 0.00 0.16 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-10 4 nd 23 170 74 20.97 35.05 0.01 0.01 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-10 4 nd 23 170 98 19.40 34.93 0.49 0.12 0.09 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-10 4 nd 23 170 100 19.41 34.93 0.46 0.11 0.05 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-10 4 nd 23 170 149 17.43 34.72 3.59 0.22 0.22 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-11 4B nd 23 174.92 0 nd nd 0.01 0.00 0.13 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-11 4B nd 23 174.92 5 26.25 35.32 0.01 0.00 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-11 4B nd 23 174.92 10 26.26 35.32 0.01 0.00 0.16 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-11 4B nd 23 174.92 19 26.26 35.32 0.01 0.00 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-11 4B nd 23 174.92 30 26.26 35.32 0.01 0.01 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-11 4B nd 23 174.92 49 26.27 35.32 0.01 0.00 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-11 4B nd 23 174.92 75 26.27 35.32 0.01 0.01 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-11 4B nd 23 174.92 100 23.73 35.37 0.01 0.02 0.15 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-11 4B nd 23 174.92 109 22.37 35.32 0.11 0.05 0.13 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-11 4B nd 23 174.92 150 20.10 35.09 1.19 0.13 0.03 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-13 5 nd 23 -180 0 nd nd 0.01 0.01 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-13 5 nd 23 -180 5 26.48 35.33 0.01 0.01 0.19 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-13 5 nd 23 -180 9 26.43 35.32 0.01 0.01 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-13 5 nd 23 -180 19 26.41 35.32 0.01 0.01 0.19 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-13 5 nd 23 -180 30 26.41 35.32 0.01 0.01 0.26 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-13 5 nd 23 -180 51 26.41 35.32 0.01 0.01 0.19 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-13 5 nd 23 -180 74 26.36 35.32 0.01 0.01 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-13 5 nd 23 -180 100 25.52 35.34 0.01 0.02 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-13 5 nd 23 -180 119 23.39 35.33 0.01 0.03 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-13 5 nd 23 -180 149 20.80 35.15 0.30 0.07 0.16 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-15 6 nd 23 -170 0 nd nd 0.01 0.04 0.23 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-15 6 nd 23 -170 5 25.32 35.24 0.01 0.03 0.20 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-15 6 nd 23 -170 9 25.32 35.24 0.01 0.04 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-15 6 nd 23 -170 20 25.33 35.24 0.01 0.04 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-15 6 nd 23 -170 30 25.33 35.24 0.01 0.04 0.16 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-15 6 nd 23 -170 49 25.33 35.24 0.01 0.04 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-15 6 nd 23 -170 76 25.33 35.24 0.03 0.04 0.19 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-15 6 nd 23 -170 98 23.75 35.23 0.22 0.10 0.24 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-15 6 nd 23 -170 110 23.32 35.24 0.39 0.12 0.16 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-15 6 nd 23 -170 150 20.51 35.12 2.09 0.22 0.20 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-17 7 nd 23 -165 0 nd nd 0.01 0.02 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-17 7 nd 23 -165 5 25.07 35.33 0.01 0.03 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-17 7 nd 23 -165 10 25.08 35.33 0.01 0.02 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-17 7 nd 23 -165 20 25.08 35.33 0.01 0.02 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-17 7 nd 23 -165 30 25.08 35.33 0.01 0.02 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-17 7 nd 23 -165 50 25.09 35.33 0.01 0.02 0.16 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-17 7 nd 23 -165 75 25.09 35.33 0.01 0.02 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-17 7 nd 23 -165 97 24.11 35.30 0.06 0.05 0.15 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-17 7 nd 23 -165 99 23.91 35.31 0.04 0.05 0.16 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-17 7 nd 23 -165 125 21.65 35.19 0.66 0.07 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-17 7 nd 23 -165 148 20.32 35.12 2.26 0.19 0.16 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-18 8 nd 22.77 -158.09 0 nd nd 0.01 0.05 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-18 8 nd 22.77 -158.09 5 24.24 35.29 0.01 0.05 0.19 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-18 8 nd 22.77 -158.09 10 24.24 35.29 0.01 0.05 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-18 8 nd 22.77 -158.09 19 24.24 35.29 0.01 0.05 0.23 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-18 8 nd 22.77 -158.09 30 24.25 35.29 0.01 0.05 0.23 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-18 8 nd 22.77 -158.09 50 24.25 35.29 0.01 0.06 0.22 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-18 8 nd 22.77 -158.09 75 24.26 35.29 0.01 0.05 0.22 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-18 8 nd 22.77 -158.09 100 24.02 35.34 0.07 0.05 0.23 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-18 8 nd 22.77 -158.09 105 23.85 35.34 0.37 0.08 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2011-12-18 8 nd 22.77 -158.09 148 21.73 35.26 1.02 0.12 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-07 15 nd -23 -120 0 nd nd 0.01 0.22 0.12 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-07 15 nd -23 -120 5 25.23 36.48 0.01 0.24 0.14 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-07 15 nd -23 -120 11 25.22 36.48 0.01 0.23 0.10 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-07 15 nd -23 -120 20 25.12 36.53 0.01 0.22 0.08 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-07 15 nd -23 -120 30 24.77 36.59 0.01 0.20 0.09 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-07 15 nd -23 -120 50 24.09 36.55 0.01 0.19 0.15 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-07 15 nd -23 -120 75 23.18 36.46 0.01 0.19 0.03 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-07 15 nd -23 -120 99 22.91 36.43 0.01 0.19 0.07 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-07 15 nd -23 -120 123 22.51 36.35 0.01 0.17 0.09 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-07 15 nd -23 -120 149 22.05 36.27 0.01 0.16 0.10 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-10 16 nd -26.5 -120 0 nd nd 0.01 0.11 0.21 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-10 16 nd -26.5 -120 6 24.43 36.33 0.01 0.12 0.20 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-10 16 nd -26.5 -120 10 24.42 36.33 0.01 0.12 0.23 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-10 16 nd -26.5 -120 20 24.39 36.33 0.01 0.12 0.20 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-10 16 nd -26.5 -120 30 24.25 36.33 0.01 0.13 0.16 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-10 16 nd -26.5 -120 50 23.26 36.21 0.01 0.12 0.19 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-10 16 nd -26.5 -120 75 22.11 36.12 0.01 0.12 0.18 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-10 16 nd -26.5 -120 99 21.44 36.01 0.01 0.11 0.16 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-10 16 nd -26.5 -120 124 20.85 35.91 0.01 0.11 0.16 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-10 16 nd -26.5 -120 148 19.84 35.71 0.01 0.12 0.20 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-11 17 nd -30 -120 0 nd nd 0.01 0.08 0.17 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-11 17 nd -30 -120 5 22.65 35.71 0.01 0.09 0.17 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-11 17 nd -30 -120 10 22.64 35.71 0.01 0.09 0.16 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-11 17 nd -30 -120 20 22.35 35.69 0.01 0.09 0.16 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-11 17 nd -30 -120 30 22.23 35.67 0.01 0.09 0.17 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-11 17 nd -30 -120 49 20.07 35.55 0.01 0.09 0.16 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-11 17 nd -30 -120 75 19.10 35.39 0.01 0.10 0.16 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-11 17 nd -30 -120 100 18.16 35.26 0.01 0.12 0.16 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-11 17 nd -30 -120 125 17.44 35.15 0.01 0.13 0.17 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-11 17 nd -30 -120 150 16.81 35.07 0.10 0.16 0.17 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-13 18 nd -30 -107 0 nd nd 0.01 0.12 0.18 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-13 18 nd -30 -107 5 21.74 35.57 0.01 0.13 0.19 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-13 18 nd -30 -107 10 21.73 35.57 0.01 0.13 0.16 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-13 18 nd -30 -107 20 21.74 35.56 0.01 0.13 0.17 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-13 18 nd -30 -107 31 20.36 35.43 0.01 0.13 0.18 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-13 18 nd -30 -107 50 19.67 35.48 0.01 0.12 0.18 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-13 18 nd -30 -107 75 19.12 35.47 0.01 0.12 0.18 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-13 18 nd -30 -107 100 18.73 35.44 0.01 0.13 0.16 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-13 18 nd -30 -107 124 17.94 35.28 0.01 0.14 0.14 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-13 18 nd -30 -107 149 17.58 35.24 0.05 0.17 0.12 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-16 19 nd -30 -100 0 nd nd 0.01 0.16 0.15 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-16 19 nd -30 -100 5 22.07 35.31 0.01 0.15 0.17 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-16 19 nd -30 -100 10 21.70 35.31 0.01 0.16 0.18 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-16 19 nd -30 -100 19 21.55 35.35 0.01 0.15 0.19 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-16 19 nd -30 -100 30 19.91 35.08 0.01 0.16 0.15 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-16 19 nd -30 -100 50 19.01 35.27 0.01 0.14 0.19 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-16 19 nd -30 -100 75 18.66 35.36 0.01 0.14 0.16 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-16 19 nd -30 -100 99 18.28 35.33 0.01 0.14 0.13 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-16 19 nd -30 -100 125 17.44 35.13 0.03 0.17 0.12 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-16 19 nd -30 -100 126 17.42 35.12 0.05 0.18 0.12 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-16 19 nd -30 -100 150 16.88 35.06 0.89 0.21 0.12 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-16 20 nd -26.5 -100 0 nd nd 0.01 0.18 0.16 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-16 20 nd -26.5 -100 5 23.59 35.94 0.01 0.19 0.16 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-16 20 nd -26.5 -100 10 23.53 35.94 0.01 0.19 0.16 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-16 20 nd -26.5 -100 20 23.40 35.93 0.01 0.19 0.18 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-16 20 nd -26.5 -100 29 23.26 35.92 0.01 0.19 0.17 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-16 20 nd -26.5 -100 49 20.53 35.50 0.01 0.19 0.15 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-16 20 nd -26.5 -100 75 19.55 35.48 0.01 0.18 0.15 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-16 20 nd -26.5 -100 99 19.13 35.49 0.01 0.18 0.17 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-16 20 nd -26.5 -100 124 18.70 35.42 0.01 0.19 0.16 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-16 20 nd -26.5 -100 149 18.59 35.45 0.02 0.19 0.14 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-17 21 nd -23 -100 0 nd nd 0.01 0.26 0.20 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-17 21 nd -23 -100 5 24.12 35.87 0.01 0.26 0.04 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-17 21 nd -23 -100 10 23.94 35.87 0.01 0.30 0.21 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-17 21 nd -23 -100 20 23.75 35.87 0.01 0.30 0.20 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-17 21 nd -23 -100 29 23.47 35.87 0.01 0.29 0.20 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-17 21 nd -23 -100 49 20.89 35.73 0.01 0.25 0.17 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-17 21 nd -23 -100 75 20.28 35.71 0.01 0.23 0.17 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-17 21 nd -23 -100 99 19.58 35.63 0.01 0.21 0.10 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-17 21 nd -23 -100 124 19.20 35.58 0.01 0.23 0.08 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-17 21 nd -23 -100 149 19.04 35.55 0.03 0.24 0.15 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-20 22 nd -20 -100 0 nd nd 0.02 0.34 0.28 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-20 22 nd -20 -100 5 24.33 35.93 0.02 0.34 0.27 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-20 22 nd -20 -100 10 24.34 35.93 0.02 0.36 0.31 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-20 22 nd -20 -100 21 24.33 35.93 0.02 0.36 0.29 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-20 22 nd -20 -100 30 22.93 35.93 0.01 0.30 0.17 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-20 22 nd -20 -100 49 22.38 35.94 0.01 0.30 0.22 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-20 22 nd -20 -100 74 20.91 35.84 0.01 0.30 0.21 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-20 22 nd -20 -100 99 20.38 35.81 0.01 0.27 0.15 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-20 22 nd -20 -100 125 20.05 35.78 0.01 0.27 0.12 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-20 22 nd -20 -100 148 19.68 35.72 0.13 0.28 0.14 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-11-10 2012-01-20 22 nd -20 -100 151 19.64 35.70 0.27 0.28 0.18 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-14 5 nd 35 160 0 nd nd 0.01 0.01 0.09 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-14 5 nd 35 160 5 23.45 34.65 0.01 0.01 0.10 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-14 5 nd 35 160 10 22.59 34.67 0.01 0.01 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-14 5 nd 35 160 20 21.82 34.70 0.01 0.01 0.10 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-14 5 nd 35 160 30 20.70 34.76 0.01 0.02 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-14 5 nd 35 160 39 20.13 34.80 0.06 0.02 0.09 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-14 5 nd 35 160 50 19.52 34.81 0.00 0.04 0.09 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-14 5 nd 35 160 63 18.86 34.89 1.44 0.16 0.10 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-14 5 nd 35 160 75 18.56 34.89 2.18 0.14 0.09 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-14 5 nd 35 160 99 17.63 34.92 2.73 0.19 0.07 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-14 5 nd 35 160 149 17.03 34.90 3.73 0.25 0.06 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-16 7 nd 30 160 0 nd nd 0.01 0.00 0.07 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-16 7 nd 30 160 5 27.18 34.83 0.01 0.00 0.08 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-16 7 nd 30 160 10 27.02 34.86 0.01 0.00 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-16 7 nd 30 160 20 25.78 35.15 0.01 0.00 0.08 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-16 7 nd 30 160 30 24.63 35.10 0.01 0.00 0.08 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-16 7 nd 30 160 40 21.96 34.98 0.01 0.01 0.08 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-16 7 nd 30 160 50 20.70 34.94 0.01 0.01 0.08 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-16 7 nd 30 160 75 18.27 34.78 1.22 0.13 0.08 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-16 7 nd 30 160 86 17.80 34.74 1.95 0.17 0.10 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-16 7 nd 30 160 99 17.42 34.72 2.82 0.22 0.03 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-16 7 nd 30 160 150 16.89 34.70 4.02 0.26 0.08 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-17 8 nd 25 160 0 nd nd 0.01 0.00 0.10 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-17 8 nd 25 160 5 28.71 35.38 0.01 0.00 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-17 8 nd 25 160 10 28.56 35.38 0.01 0.00 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-17 8 nd 25 160 20 28.50 35.38 0.01 0.00 0.11 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-17 8 nd 25 160 30 28.43 35.37 0.01 0.01 0.11 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-17 8 nd 25 160 40 25.51 35.23 0.01 0.00 0.07 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-17 8 nd 25 160 50 24.39 35.23 0.01 0.00 0.10 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-17 8 nd 25 160 75 22.95 35.15 0.01 0.00 0.08 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-17 8 nd 25 160 100 21.41 35.03 0.01 0.01 0.07 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-17 8 nd 25 160 137 18.64 34.81 0.44 0.07 0.11 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-17 8 nd 25 160 149 18.13 34.78 2.24 0.18 0.04 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-19 9 nd 20 160 0 nd nd 0.01 0.00 0.13 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-19 9 nd 20 160 5 29.17 34.93 0.01 0.00 0.13 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-19 9 nd 20 160 10 29.17 34.93 0.01 0.01 0.16 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-19 9 nd 20 160 20 29.18 34.93 0.01 0.00 0.13 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-19 9 nd 20 160 31 29.18 34.93 0.01 0.00 0.13 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-19 9 nd 20 160 40 29.17 34.93 0.01 0.00 0.11 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-19 9 nd 20 160 50 29.12 34.93 0.01 0.00 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-19 9 nd 20 160 76 26.02 35.04 0.01 0.00 0.10 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-19 9 nd 20 160 98 24.45 35.20 0.04 0.03 0.09 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-19 9 nd 20 160 126 22.91 35.15 0.00 0.02 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-19 9 nd 20 160 149 20.95 35.04 1.27 0.12 0.06 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-22 10 nd 15 160 0 nd nd 0.01 0.07 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-22 10 nd 15 160 5 29.34 34.91 0.01 0.07 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-22 10 nd 15 160 10 29.32 34.91 0.01 0.08 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-22 10 nd 15 160 20 29.22 34.91 0.01 0.08 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-22 10 nd 15 160 30 29.18 34.92 0.01 0.08 0.15 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-22 10 nd 15 160 40 29.17 34.92 0.01 0.08 0.16 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-22 10 nd 15 160 50 28.73 35.01 0.01 0.07 0.16 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-22 10 nd 15 160 74 27.90 35.06 0.01 0.05 0.13 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-22 10 nd 15 160 99 27.60 35.07 0.01 0.03 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-22 10 nd 15 160 122 26.39 35.14 0.04 0.04 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-07-22 10 nd 15 160 149 24.29 35.21 0.59 0.14 0.07 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-01 12 nd 20 148 0 nd nd 0.01 0.01 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-01 12 nd 20 148 5 29.00 34.68 0.01 0.01 0.13 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-01 12 nd 20 148 11 29.00 34.68 0.01 0.01 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-01 12 nd 20 148 20 29.01 34.69 0.01 0.01 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-01 12 nd 20 148 29 28.88 34.79 0.01 0.00 0.13 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-01 12 nd 20 148 40 28.09 34.99 0.01 0.00 0.13 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-01 12 nd 20 148 52 26.58 35.07 0.01 0.01 0.11 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-01 12 nd 20 148 75 24.08 35.09 0.01 0.01 0.10 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-01 12 nd 20 148 101 23.09 35.08 0.01 0.01 0.09 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-01 12 nd 20 148 129 20.61 34.98 0.46 0.06 0.10 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-01 12 nd 20 148 150 19.38 34.86 2.28 0.17 0.08 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-05 14 nd 24 143.21 0 nd nd 0.01 0.00 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-05 14 nd 24 143.21 5 28.65 34.62 0.01 0.00 0.11 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-05 14 nd 24 143.21 9 28.65 34.62 0.01 0.00 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-05 14 nd 24 143.21 21 28.65 34.62 0.01 0.00 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-05 14 nd 24 143.21 30 28.63 34.62 0.01 0.00 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-05 14 nd 24 143.21 39 27.55 34.71 0.01 0.00 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-05 14 nd 24 143.21 49 25.76 34.87 0.01 0.00 0.11 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-05 14 nd 24 143.21 72 23.24 34.96 0.01 0.00 0.10 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-05 14 nd 24 143.21 88 22.07 35.00 0.01 0.01 0.09 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-05 14 nd 24 143.21 99 21.34 34.95 0.01 0.01 0.10 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-05 14 nd 24 143.21 149 19.24 34.84 1.28 0.10 0.08 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-07 15 nd 28 138 0 nd nd 0.01 0.00 0.10 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-07 15 nd 28 138 5 27.57 34.33 0.01 0.00 0.10 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-07 15 nd 28 138 9 27.43 34.34 0.01 0.00 0.10 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-07 15 nd 28 138 20 26.41 34.38 0.01 0.00 0.10 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-07 15 nd 28 138 30 26.00 34.34 0.01 0.00 0.10 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-07 15 nd 28 138 39 24.88 34.35 0.01 0.00 0.10 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-07 15 nd 28 138 50 21.89 34.63 0.02 0.00 0.10 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-07 15 nd 28 138 75 20.66 34.78 0.27 0.04 0.09 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-07 15 nd 28 138 80 20.60 34.79 1.04 0.09 0.09 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-07 15 nd 28 138 99 19.90 34.81 1.85 0.13 0.10 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-07 15 nd 28 138 149 19.02 34.80 2.15 0.15 0.10 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-09 16 nd 31 134.07 0 nd nd 0.01 0.01 0.10 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-09 16 nd 31 134.07 6 27.47 34.27 0.01 0.01 0.09 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-09 16 nd 31 134.07 10 27.35 34.26 0.01 0.01 0.09 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-09 16 nd 31 134.07 20 27.21 34.26 0.01 0.00 0.09 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-09 16 nd 31 134.07 30 27.11 34.26 0.01 0.01 0.09 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-09 16 nd 31 134.07 40 22.98 34.52 0.01 0.01 0.10 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-09 16 nd 31 134.07 50 22.40 34.58 0.01 0.01 0.09 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-09 16 nd 31 134.07 75 21.06 34.78 0.01 0.01 0.09 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-09 16 nd 31 134.07 100 19.81 34.82 0.00 0.07 0.05 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-09 16 nd 31 134.07 105 19.66 34.82 0.07 0.04 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-12-3 2012-08-09 16 nd 31 134.07 150 18.91 34.79 2.34 0.16 0.06 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2013-12-16 0 nd 20 160.01 0 nd nd 0.02 0.02 0.32 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2013-12-16 0 nd 20 160.01 5 27.75 35.02 0.01 0.01 0.30 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2013-12-16 0 nd 20 160.01 10 27.74 35.02 0.01 0.01 0.30 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2013-12-16 0 nd 20 160.01 20 27.72 35.01 0.01 0.01 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2013-12-16 0 nd 20 160.01 31 27.67 35.01 0.01 0.01 0.25 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2013-12-16 0 nd 20 160.01 50 27.67 35.01 0.01 0.01 0.19 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2013-12-16 0 nd 20 160.01 75 27.21 35.02 0.02 0.01 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2013-12-16 0 nd 20 160.01 100 24.40 35.16 0.01 0.01 0.15 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2013-12-16 0 nd 20 160.01 124 23.19 35.12 0.20 0.04 0.13 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2013-12-16 0 nd 20 160.01 126 23.15 35.12 0.26 0.05 0.24 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2013-12-16 0 nd 20 160.01 149 20.36 35.01 2.38 0.17 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-02 4 nd -15 -170 0 nd nd 0.02 0.21 0.23 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-02 4 nd -15 -170 10 29.04 35.25 0.02 0.22 0.21 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-02 4 nd -15 -170 21 29.04 35.25 0.01 0.22 0.21 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-02 4 nd -15 -170 30 29.01 35.26 0.01 0.22 0.19 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-02 4 nd -15 -170 50 28.41 35.66 0.01 0.23 0.21 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-02 4 nd -15 -170 76 27.44 35.77 0.01 0.21 0.20 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-02 4 nd -15 -170 98 26.75 35.90 0.01 0.23 0.17 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-02 4 nd -15 -170 126 25.68 36.05 0.59 0.31 0.11 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-02 4 nd -15 -170 139 24.75 36.21 2.09 0.41 0.06 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-02 4 nd -15 -170 149 24.57 36.22 3.02 0.47 0.03 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-05 5 nd -20 -170.06 0 nd nd 0.02 0.13 0.20 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-05 5 nd -20 -170.06 4 27.80 35.45 0.01 0.13 0.18 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-05 5 nd -20 -170.06 9 27.79 35.45 0.01 0.13 0.18 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-05 5 nd -20 -170.06 20 27.75 35.44 0.01 0.13 0.17 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-05 5 nd -20 -170.06 30 27.66 35.44 0.01 0.13 0.17 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-05 5 nd -20 -170.06 49 26.64 35.53 0.01 0.10 0.17 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-05 5 nd -20 -170.06 75 25.43 35.60 0.01 0.07 0.14 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-05 5 nd -20 -170.06 99 24.43 35.61 0.01 0.07 0.14 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-05 5 nd -20 -170.06 124 23.63 35.57 0.01 0.09 0.12 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-05 5 nd -20 -170.06 150 23.34 35.59 0.11 0.13 0.10 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-08 6 nd -25.01 -170.7 0 nd nd 0.01 0.03 0.18 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-08 6 nd -25.01 -170.7 5 26.34 35.55 0.01 0.03 0.17 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-08 6 nd -25.01 -170.7 10 26.34 35.55 0.01 0.03 0.14 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-08 6 nd -25.01 -170.7 21 26.32 35.55 0.01 0.03 0.17 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-08 6 nd -25.01 -170.7 30 25.41 35.54 0.01 0.03 0.16 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-08 6 nd -25.01 -170.7 50 23.00 35.54 0.01 0.03 0.12 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-08 6 nd -25.01 -170.7 75 22.36 35.54 0.01 0.07 0.13 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-08 6 nd -25.01 -170.7 100 21.32 35.58 0.40 0.15 0.07 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-08 6 nd -25.01 -170.7 109 21.10 35.60 0.93 0.20 0.10 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-08 6 nd -25.01 -170.7 124 20.53 35.61 2.26 0.27 0.05 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-08 6 nd -25.01 -170.7 148 19.64 35.58 3.22 0.33 0.03 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-09 7 nd -30 -170 0 nd nd 0.01 0.03 0.14 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-09 7 nd -30 -170 10 23.88 35.44 0.01 0.03 0.14 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-09 7 nd -30 -170 21 23.75 35.44 0.01 0.03 0.12 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-09 7 nd -30 -170 31 23.04 35.46 0.01 0.03 0.11 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-09 7 nd -30 -170 49 20.07 35.48 0.01 0.06 0.12 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-09 7 nd -30 -170 75 18.11 35.44 0.01 0.10 0.12 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-09 7 nd -30 -170 99 17.25 35.47 0.03 0.14 0.11 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-09 7 nd -30 -170 107 16.79 35.46 0.84 0.22 0.06 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-09 7 nd -30 -170 124 16.51 35.45 3.23 0.35 0.02 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-09 7 nd -30 -170 149 15.96 35.42 4.87 0.45 0.04 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-12 8 nd -35 -170.07 0 nd nd 0.01 0.08 0.12 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-12 8 nd -35 -170.07 6 22.01 35.23 0.01 0.08 0.12 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-12 8 nd -35 -170.07 10 22.01 35.23 0.01 0.08 0.12 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-12 8 nd -35 -170.07 21 21.60 35.28 0.01 0.08 0.11 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-12 8 nd -35 -170.07 30 21.83 35.22 0.01 0.08 0.11 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-12 8 nd -35 -170.07 49 20.37 35.38 0.01 0.08 0.12 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-12 8 nd -35 -170.07 75 17.65 35.31 0.01 0.08 0.12 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-12 8 nd -35 -170.07 99 16.79 35.32 0.01 0.10 0.10 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-12 8 nd -35 -170.07 123 15.94 35.29 0.15 0.18 0.09 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-12 8 nd -35 -170.07 126 15.85 35.29 0.68 0.28 0.02 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-13-7 2014-01-12 8 nd -35 -170.07 148 15.42 35.31 4.39 0.44 0.02 2 South Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-06-27 0 nd 19.99 159.97 0 nd nd 0.01 0.00 0.36 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-06-27 0 nd 19.99 159.97 0 nd nd 0.01 0.01 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-06-27 0 nd 19.99 159.97 5 28.73 35.43 0.01 0.00 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-06-27 0 nd 19.99 159.97 10 28.70 35.42 0.01 0.00 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-06-27 0 nd 19.99 159.97 20 27.94 35.43 0.01 0.00 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-06-27 0 nd 19.99 159.97 28 28.46 35.43 0.01 0.00 0.22 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-06-27 0 nd 19.99 159.97 30 26.83 35.44 0.01 0.00 0.23 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-06-27 0 nd 19.99 159.97 50 25.18 35.33 0.01 0.01 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-06-27 0 nd 19.99 159.97 55 26.16 35.39 0.01 0.00 0.24 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-06-27 0 nd 19.99 159.97 74 24.08 35.31 0.01 0.01 0.25 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-06-27 0 nd 19.99 159.97 100 23.14 35.27 0.01 0.01 0.22 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-06-27 0 nd 19.99 159.97 106 23.85 35.29 0.01 0.01 0.19 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-06-27 0 nd 19.99 159.97 119 22.07 35.16 0.08 0.03 0.24 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-06-27 0 nd 19.99 159.97 124 21.98 35.14 0.17 0.04 0.26 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-06-27 0 nd 19.99 159.97 148 20.09 34.96 1.38 0.13 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-08 4 nd 15.01 -170.02 0 nd nd 0.01 0.14 0.30 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-08 4 nd 15.01 -170.02 0 nd nd 0.01 0.14 0.20 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-08 4 nd 15.01 -170.02 5 27.51 34.99 0.01 0.14 0.29 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-08 4 nd 15.01 -170.02 10 27.52 34.99 0.01 0.14 0.36 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-08 4 nd 15.01 -170.02 19 27.50 34.99 0.01 0.14 0.27 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-08 4 nd 15.01 -170.02 20 27.52 35.00 0.01 0.14 0.19 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-08 4 nd 15.01 -170.02 30 27.52 35.00 0.01 0.14 0.34 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-08 4 nd 15.01 -170.02 48 27.51 34.99 0.01 0.14 0.26 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-08 4 nd 15.01 -170.02 50 27.52 35.00 0.01 0.14 0.36 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-08 4 nd 15.01 -170.02 75 27.46 34.99 0.01 0.14 0.39 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-08 4 nd 15.01 -170.02 100 25.85 35.09 0.01 0.13 0.37 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-08 4 nd 15.01 -170.02 116 25.33 35.16 0.03 0.13 0.26 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-08 4 nd 15.01 -170.02 125 23.85 35.23 0.06 0.15 0.27 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-08 4 nd 15.01 -170.02 134 23.06 35.18 0.36 0.19 0.25 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-08 4 nd 15.01 -170.02 149 22.46 35.20 0.59 0.21 0.31 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-09 5 nd 20.02 -169.98 0 nd nd 0.01 0.12 0.25 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-09 5 nd 20.02 -169.98 0 nd nd 0.01 0.12 0.19 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-09 5 nd 20.02 -169.98 5 27.49 35.16 0.01 0.12 0.26 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-09 5 nd 20.02 -169.98 10 27.49 35.16 0.01 0.12 0.27 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-09 5 nd 20.02 -169.98 20 27.48 35.16 0.01 0.12 0.26 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-09 5 nd 20.02 -169.98 20 27.49 35.18 0.01 0.11 0.29 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-09 5 nd 20.02 -169.98 30 27.36 35.21 0.01 0.10 0.24 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-09 5 nd 20.02 -169.98 47 26.34 35.33 0.01 0.06 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-09 5 nd 20.02 -169.98 51 26.17 35.39 0.01 0.05 0.20 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-09 5 nd 20.02 -169.98 74 23.96 35.39 0.01 0.05 0.22 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-09 5 nd 20.02 -169.98 100 22.62 35.39 0.01 0.07 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-09 5 nd 20.02 -169.98 100 23.06 35.46 0.01 0.05 0.19 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-09 5 nd 20.02 -169.98 124 22.10 35.36 0.06 0.09 0.20 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-09 5 nd 20.02 -169.98 138 21.40 35.26 0.72 0.15 0.23 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-09 5 nd 20.02 -169.98 144 21.17 35.26 1.59 0.19 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-09 5 nd 20.02 -169.98 151 21.03 35.21 1.95 0.24 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-10 6 nd 24.04 -170 0 nd nd 0.01 0.04 0.20 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-10 6 nd 24.04 -170 0 nd nd 0.01 0.04 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-10 6 nd 24.04 -170 5 26.51 35.58 0.01 0.03 0.22 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-10 6 nd 24.04 -170 10 26.50 35.58 0.01 0.04 0.23 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-10 6 nd 24.04 -170 20 26.38 35.58 0.01 0.03 0.24 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-10 6 nd 24.04 -170 25 26.23 35.48 0.01 0.03 0.19 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-10 6 nd 24.04 -170 30 26.01 35.54 0.01 0.02 0.19 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-10 6 nd 24.04 -170 50 22.64 35.39 0.01 0.02 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-10 6 nd 24.04 -170 54 21.79 35.33 0.01 0.03 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-10 6 nd 24.04 -170 75 20.78 35.26 0.01 0.04 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-10 6 nd 24.04 -170 100 20.18 35.20 0.01 0.05 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-10 6 nd 24.04 -170 108 19.46 35.12 0.94 0.12 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-10 6 nd 24.04 -170 113 19.10 35.08 0.42 0.09 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-10 6 nd 24.04 -170 124 18.52 34.98 2.20 0.21 0.15 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-10 6 nd 24.04 -170 149 17.99 34.93 2.55 0.23 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-20 7 nd 30.04 -170 0 nd nd 0.03 0.02 0.16 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-20 7 nd 30.04 -170 0 nd nd 0.01 0.02 0.16 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-20 7 nd 30.04 -170 5 26.01 35.21 0.04 0.03 0.15 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-20 7 nd 30.04 -170 10 25.85 35.27 0.06 0.02 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-20 7 nd 30.04 -170 19 25.60 35.20 0.03 0.02 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-20 7 nd 30.04 -170 27 25.43 35.26 0.01 0.02 0.08 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-20 7 nd 30.04 -170 30 21.25 35.10 0.11 0.02 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-20 7 nd 30.04 -170 50 19.44 34.97 0.07 0.04 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-20 7 nd 30.04 -170 50 19.87 34.99 0.01 0.03 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-20 7 nd 30.04 -170 73 17.57 34.79 0.05 0.07 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-20 7 nd 30.04 -170 93 16.98 34.76 0.07 0.07 0.28 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-20 7 nd 30.04 -170 99 16.69 34.74 0.78 0.19 0.09 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-20 7 nd 30.04 -170 103 16.37 34.71 2.84 0.31 0.11 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-20 7 nd 30.04 -170 124 15.99 34.67 4.09 0.42 0.04 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-20 7 nd 30.04 -170 140 15.69 34.63 4.36 0.30 0.19 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-20 7 nd 30.04 -170 148 15.47 34.60 4.60 0.36 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-21 8 nd 35.01 -170 0 nd nd 0.01 0.01 0.20 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-21 8 nd 35.01 -170 0 nd nd 0.01 0.02 0.19 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-21 8 nd 35.01 -170 5 23.75 34.59 0.01 0.02 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-21 8 nd 35.01 -170 10 23.74 34.59 0.01 0.02 0.19 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-21 8 nd 35.01 -170 19 22.82 34.59 0.01 0.02 0.23 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-21 8 nd 35.01 -170 22 22.68 34.58 0.01 0.03 0.15 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-21 8 nd 35.01 -170 30 17.84 34.56 0.01 0.03 0.16 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-21 8 nd 35.01 -170 40 17.14 34.58 0.01 0.04 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-21 8 nd 35.01 -170 49 16.12 34.55 0.08 0.04 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-21 8 nd 35.01 -170 66 15.34 34.52 2.01 0.14 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-21 8 nd 35.01 -170 70 15.55 34.51 1.84 0.18 0.22 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-21 8 nd 35.01 -170 74 15.07 34.51 3.09 0.28 0.15 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-21 8 nd 35.01 -170 99 14.59 34.51 5.92 0.40 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-21 8 nd 35.01 -170 99 14.76 34.53 5.61 0.38 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-21 8 nd 35.01 -170 123 14.18 34.48 6.08 0.44 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-14-3 2014-07-21 8 nd 35.01 -170 151 13.94 34.47 6.75 0.41 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-21 6 nd 22.59 -120 0 nd nd 0.01 0.18 0.23 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-21 6 nd 22.59 -120 0 nd nd 0.01 0.19 0.20 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-21 6 nd 22.59 -120 6 24.97 34.40 0.01 0.18 0.22 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-21 6 nd 22.59 -120 11 24.95 34.40 0.01 0.19 0.22 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-21 6 nd 22.59 -120 20 24.94 34.41 0.01 0.19 0.22 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-21 6 nd 22.59 -120 28 24.90 34.41 0.01 0.21 0.19 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-21 6 nd 22.59 -120 31 23.97 34.35 0.01 0.19 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-21 6 nd 22.59 -120 51 22.57 34.25 0.01 0.21 0.20 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-21 6 nd 22.59 -120 51 22.60 34.27 0.01 0.22 0.19 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-21 6 nd 22.59 -120 76 20.49 34.05 0.01 0.23 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-21 6 nd 22.59 -120 99 18.67 33.92 0.06 0.24 0.16 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-21 6 nd 22.59 -120 104 18.75 33.94 0.06 0.24 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-21 6 nd 22.59 -120 119 17.14 33.90 2.38 0.68 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-24 7 nd 23 -130 0 nd nd 0.01 0.16 0.19 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-24 7 nd 23 -130 0 nd nd 0.01 0.17 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-24 7 nd 23 -130 6 24.32 34.68 0.01 0.17 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-24 7 nd 23 -130 10 24.25 34.67 0.01 0.17 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-24 7 nd 23 -130 20 24.00 34.67 0.01 0.17 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-24 7 nd 23 -130 26 23.96 34.66 0.01 0.18 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-24 7 nd 23 -130 31 23.95 34.67 0.01 0.18 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-24 7 nd 23 -130 50 22.27 34.65 0.01 0.16 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-24 7 nd 23 -130 57 20.99 34.59 0.01 0.13 0.16 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-24 7 nd 23 -130 74 20.56 34.56 0.01 0.15 0.15 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-24 7 nd 23 -130 100 19.91 34.62 0.01 0.13 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-24 7 nd 23 -130 116 19.19 34.61 0.03 0.12 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-24 7 nd 23 -130 125 19.15 34.64 0.01 0.12 0.13 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-24 7 nd 23 -130 140 18.62 34.63 0.57 0.17 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-24 7 nd 23 -130 150 17.87 34.50 1.70 0.29 0.08 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-27 8 nd 22.59 -140 0 nd nd 0.01 0.06 0.20 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-27 8 nd 22.59 -140 0 nd nd 0.01 0.06 0.20 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-27 8 nd 22.59 -140 5 24.20 35.03 0.01 0.07 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-27 8 nd 22.59 -140 10 24.20 35.03 0.01 0.07 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-27 8 nd 22.59 -140 20 24.18 35.03 0.01 0.07 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-27 8 nd 22.59 -140 24 23.96 35.05 0.01 0.07 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-27 8 nd 22.59 -140 30 24.11 35.03 0.01 0.07 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-27 8 nd 22.59 -140 51 23.50 35.07 0.01 0.06 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-27 8 nd 22.59 -140 51 23.26 35.12 0.01 0.05 0.20 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-27 8 nd 22.59 -140 75 21.43 34.94 0.01 0.09 0.19 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-27 8 nd 22.59 -140 100 21.11 35.05 0.01 0.08 0.19 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-27 8 nd 22.59 -140 110 20.13 34.84 0.01 0.11 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-27 8 nd 22.59 -140 116 20.22 34.99 0.70 0.17 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-27 8 nd 22.59 -140 125 20.09 35.00 1.03 0.18 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-27 8 nd 22.59 -140 150 18.97 34.84 1.16 0.18 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-30 9 nd 23.01 -150 0 nd nd 0.01 0.10 0.23 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-30 9 nd 23.01 -150 0 nd nd 0.01 0.10 0.24 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-30 9 nd 23.01 -150 5 26.52 34.66 0.01 0.10 0.22 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-30 9 nd 23.01 -150 10 26.50 34.66 0.01 0.10 0.23 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-30 9 nd 23.01 -150 20 26.50 34.68 0.01 0.08 0.23 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-30 9 nd 23.01 -150 25 26.46 34.63 0.01 0.10 0.24 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-30 9 nd 23.01 -150 31 26.44 34.88 0.01 0.05 0.22 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-30 9 nd 23.01 -150 50 25.95 35.22 0.01 0.02 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-30 9 nd 23.01 -150 51 25.85 34.92 0.01 0.04 0.22 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-30 9 nd 23.01 -150 75 24.55 35.18 0.01 0.03 0.22 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-30 9 nd 23.01 -150 100 22.64 35.21 0.01 0.04 0.19 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-30 9 nd 23.01 -150 106 22.21 35.18 0.01 0.07 0.19 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-30 9 nd 23.01 -150 118 21.74 35.14 0.63 0.21 0.09 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-30 9 nd 23.01 -150 124 21.41 35.11 0.96 0.18 0.15 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-08-30 9 nd 23.01 -150 149 20.23 34.98 2.87 0.38 0.03 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-02 10 nd 21.3 -160 0 nd nd 0.01 0.07 0.20 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-02 10 nd 21.3 -160 0 nd nd 0.01 0.06 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-02 10 nd 21.3 -160 6 27.92 34.70 0.01 0.06 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-02 10 nd 21.3 -160 11 27.93 34.70 0.01 0.07 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-02 10 nd 21.3 -160 20 27.93 34.70 0.01 0.07 0.20 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-02 10 nd 21.3 -160 25 27.96 34.70 0.01 0.06 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-02 10 nd 21.3 -160 31 27.91 34.69 0.01 0.07 0.22 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-02 10 nd 21.3 -160 48 27.16 34.62 0.01 0.07 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-02 10 nd 21.3 -160 49 27.07 34.55 0.01 0.09 0.21 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-02 10 nd 21.3 -160 75 25.36 34.88 0.01 0.07 0.20 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-02 10 nd 21.3 -160 101 22.86 35.05 0.09 0.14 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-02 10 nd 21.3 -160 104 22.82 35.03 0.04 0.15 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-02 10 nd 21.3 -160 111 22.90 35.05 0.18 0.15 0.16 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-02 10 nd 21.3 -160 125 22.25 35.11 0.25 0.14 0.16 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-02 10 nd 21.3 -160 148 21.03 35.10 0.92 0.19 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-02 10 nd 21.3 -160 149 21.10 35.10 0.80 0.17 0.13 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-13 11 nd 21.3 -170 0 nd nd 0.01 0.04 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-13 11 nd 21.3 -170 0 nd nd 0.01 0.04 0.16 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-13 11 nd 21.3 -170 5 28.73 34.90 0.01 0.05 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-13 11 nd 21.3 -170 10 28.75 34.93 0.01 0.04 0.19 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-13 11 nd 21.3 -170 20 28.63 35.10 0.01 0.02 0.19 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-13 11 nd 21.3 -170 29 28.29 35.12 0.01 0.01 0.19 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-13 11 nd 21.3 -170 29 28.35 35.04 0.01 0.03 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-13 11 nd 21.3 -170 51 26.81 35.15 0.01 0.01 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-13 11 nd 21.3 -170 57 25.96 35.19 0.01 0.03 0.15 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-13 11 nd 21.3 -170 74 25.20 35.23 0.01 0.01 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-13 11 nd 21.3 -170 100 23.26 35.24 0.01 0.03 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-13 11 nd 21.3 -170 108 22.21 35.19 0.01 0.08 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-13 11 nd 21.3 -170 121 21.14 35.13 0.66 0.15 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-13 11 nd 21.3 -170 124 21.70 35.17 0.97 0.17 0.11 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-13 11 nd 21.3 -170 144 19.45 35.00 1.96 0.28 0.09 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-13 11 nd 21.3 -170 148 19.67 35.01 1.87 0.27 0.06 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-16 12 nd 22.59 179.59 0 nd nd 0.01 0.03 0.16 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-16 12 nd 22.59 179.59 0 nd nd 0.01 0.02 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-16 12 nd 22.59 179.59 5 29.03 34.88 0.01 0.02 0.16 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-16 12 nd 22.59 179.59 11 29.04 34.88 0.01 0.03 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-16 12 nd 22.59 179.59 20 29.03 34.88 0.01 0.02 0.17 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-16 12 nd 22.59 179.59 25 29.02 34.92 0.01 0.01 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-16 12 nd 22.59 179.59 29 28.99 34.88 0.01 0.03 0.16 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-16 12 nd 22.59 179.59 50 27.83 34.93 0.01 0.03 0.16 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-16 12 nd 22.59 179.59 52 27.00 35.15 0.01 0.01 0.18 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-16 12 nd 22.59 179.59 74 25.48 35.27 0.01 0.03 0.15 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-16 12 nd 22.59 179.59 100 23.13 35.25 0.01 0.04 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-16 12 nd 22.59 179.59 111 22.41 35.21 0.01 0.05 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-16 12 nd 22.59 179.59 125 21.41 35.15 0.09 0.11 0.10 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-16 12 nd 22.59 179.59 131 20.99 35.12 0.41 0.11 0.11 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-16 12 nd 22.59 179.59 151 20.17 35.05 0.82 0.18 0.06 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-20 13 nd 23 169.59 0 nd nd 0.01 0.00 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-20 13 nd 23 169.59 0 nd nd 0.01 0.00 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-20 13 nd 23 169.59 5 29.40 35.10 0.01 0.00 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-20 13 nd 23 169.59 10 29.33 35.09 0.01 0.01 0.15 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-20 13 nd 23 169.59 21 29.21 35.08 0.01 0.01 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-20 13 nd 23 169.59 27 29.20 35.09 0.01 0.00 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-20 13 nd 23 169.59 31 29.17 35.08 0.01 0.01 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-20 13 nd 23 169.59 49 26.73 35.33 0.01 0.00 0.13 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-20 13 nd 23 169.59 56 26.12 35.33 0.01 0.00 0.13 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-20 13 nd 23 169.59 76 23.70 35.27 0.01 0.03 0.16 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-20 13 nd 23 169.59 99 22.32 35.21 0.01 0.04 0.11 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-20 13 nd 23 169.59 113 21.72 35.17 0.01 0.04 0.13 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-20 13 nd 23 169.59 125 20.98 35.12 0.17 0.10 0.10 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-20 13 nd 23 169.59 126 20.96 35.12 0.13 0.09 0.13 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-20 13 nd 23 169.59 149 20.18 35.07 1.00 0.21 0.04 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-22 14 nd 22.59 159.58 0 nd nd 0.01 0.00 0.15 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-22 14 nd 22.59 159.58 0 nd nd 0.01 0.00 0.19 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-22 14 nd 22.59 159.58 6 29.50 35.08 0.01 0.00 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-22 14 nd 22.59 159.58 11 29.50 35.08 0.01 0.00 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-22 14 nd 22.59 159.58 20 29.49 35.08 0.01 0.00 0.15 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-22 14 nd 22.59 159.58 28 29.11 35.08 0.01 0.00 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-22 14 nd 22.59 159.58 30 29.21 35.10 0.01 0.00 0.13 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-22 14 nd 22.59 159.58 50 27.18 35.25 0.01 0.00 0.13 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-22 14 nd 22.59 159.58 56 26.43 35.29 0.01 0.00 0.15 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-22 14 nd 22.59 159.58 74 25.10 35.30 0.01 0.00 0.13 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-22 14 nd 22.59 159.58 99 22.76 35.25 0.01 0.02 0.13 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-22 14 nd 22.59 159.58 114 22.70 35.24 0.01 0.03 0.13 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-22 14 nd 22.59 159.58 125 21.38 35.16 0.01 0.03 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-22 14 nd 22.59 159.58 145 21.31 35.14 0.03 0.04 0.11 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-22 14 nd 22.59 159.58 150 20.88 35.11 0.05 0.04 0.11 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-26 15 nd 23 150.01 0 nd nd 0.01 0.00 0.11 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-26 15 nd 23 150.01 0 nd nd 0.01 0.00 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-26 15 nd 23 150.01 5 29.49 34.84 0.01 0.00 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-26 15 nd 23 150.01 20 29.27 34.80 0.01 0.00 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-26 15 nd 23 150.01 31 28.49 34.79 0.01 0.00 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-26 15 nd 23 150.01 33 29.29 34.81 0.01 0.00 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-26 15 nd 23 150.01 50 27.38 34.85 0.01 0.00 0.11 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-26 15 nd 23 150.01 57 26.86 34.86 0.01 0.00 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-26 15 nd 23 150.01 75 23.30 35.05 0.01 0.01 0.11 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-26 15 nd 23 150.01 100 21.08 35.00 0.01 0.04 0.11 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-26 15 nd 23 150.01 103 22.17 35.09 0.01 0.03 0.11 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-26 15 nd 23 150.01 115 19.76 34.93 0.38 0.10 0.09 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-26 15 nd 23 150.01 125 19.17 34.91 0.00 0.17 0.06 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-26 15 nd 23 150.01 137 19.69 34.93 1.00 0.13 0.08 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-26 15 nd 23 150.01 149 18.71 34.89 2.43 0.24 0.04 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-29 16 nd 23 139.59 0 nd nd 0.01 0.00 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-29 16 nd 23 139.59 0 nd nd 0.01 0.00 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-29 16 nd 23 139.59 5 30.00 34.86 0.01 0.00 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-29 16 nd 23 139.59 10 29.98 34.86 0.01 0.00 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-29 16 nd 23 139.59 20 29.53 34.87 0.01 0.00 0.13 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-29 16 nd 23 139.59 25 29.90 34.84 0.01 0.00 0.11 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-29 16 nd 23 139.59 30 28.74 34.89 0.01 0.00 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-29 16 nd 23 139.59 50 25.76 35.04 0.01 0.00 0.11 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-29 16 nd 23 139.59 53 25.27 35.06 0.01 0.01 0.11 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-29 16 nd 23 139.59 75 23.94 35.17 0.01 0.02 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-29 16 nd 23 139.59 99 22.40 35.17 0.25 0.08 0.10 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-29 16 nd 23 139.59 103 22.14 35.15 0.49 0.10 0.08 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-29 16 nd 23 139.59 106 21.66 35.13 0.94 0.13 0.08 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-29 16 nd 23 139.59 124 21.09 35.10 0.00 0.15 0.06 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-29 16 nd 23 139.59 149 20.17 35.01 1.46 0.16 0.07 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-09-29 16 nd 23 139.59 149 19.67 34.99 1.84 0.20 0.06 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-10-01 17 nd 23 136.59 0 nd nd 0.01 0.00 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-10-01 17 nd 23 136.59 0 nd nd 0.01 0.00 0.15 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-10-01 17 nd 23 136.59 5 30.22 34.53 0.01 0.00 0.15 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-10-01 17 nd 23 136.59 11 30.22 34.52 0.01 0.00 0.15 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-10-01 17 nd 23 136.59 20 30.21 34.52 0.01 0.00 0.15 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-10-01 17 nd 23 136.59 28 30.07 34.53 0.01 0.00 0.15 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-10-01 17 nd 23 136.59 30 30.12 34.52 0.01 0.00 0.16 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-10-01 17 nd 23 136.59 49 29.64 34.62 0.01 0.00 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-10-01 17 nd 23 136.59 60 28.24 34.86 0.01 0.00 0.15 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-10-01 17 nd 23 136.59 75 27.72 34.92 0.01 0.00 0.16 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-10-01 17 nd 23 136.59 99 25.78 35.07 0.01 0.01 0.14 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-10-01 17 nd 23 136.59 117 24.71 35.13 0.04 0.03 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-10-01 17 nd 23 136.59 123 24.43 35.13 0.05 0.04 0.12 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669 nd KH-17-4 2017-10-01 17 nd 23 136.59 131 23.96 35.15 0.26 0.06 0.11 2 North Pacific Wet oxidation Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. 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Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-13 A10-01 nd -35.08802 -49.30228 41.7 19.618 35.33 0.43 0.05 0.12 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-13 A10-01 nd -35.08802 -49.30228 45.1 19.524 35.338 0.23 0.03 0.12 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-13 A10-01 nd -35.08802 -49.30228 71.6 18.968 36.109 0.93 0.10 0.19 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-13 A10-01 nd -35.08802 -49.30228 140 16.017 35.695 0.37 0.00 0.07 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-13 A10-01 nd -35.08802 -49.30228 189.8 15.254 35.598 0.27 0.07 0.14 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-15 A10-02 nd -29.0474 -43.02333 11.1 23.626 36.423 nd 0.00 0.39 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-15 A10-02 nd -29.0474 -43.02333 46.6 23.621 36.434 nd 0.00 0.39 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-17 A10-04 nd -22.2481 -36.83975 9.2 27.259 37.066 0.12 0.00 0.09 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-17 A10-04 nd -22.2481 -36.83975 32.5 27.231 37.065 0.07 0.00 0.16 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-17 A10-04 nd -22.2481 -36.83975 37.8 27.231 37.066 0.00 0.00 0.03 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-17 A10-04 nd -22.2481 -36.83975 47.3 27.006 37.138 0.13 0.00 0.01 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-17 A10-04 nd -22.2481 -36.83975 82.4 24.491 37.22 0.06 0.00 0.03 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-17 A10-04 nd -22.2481 -36.83975 92.3 23.952 37.169 nd 0.00 0.02 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-17 A10-04 nd -22.2481 -36.83975 107.2 23.626 37.13 nd 0.00 0.03 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-17 A10-04 nd -22.2481 -36.83975 136.6 22.837 36.964 0.10 0.00 0.02 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-17 A10-04 nd -22.2481 -36.83975 175.9 21.127 36.619 0.50 0.00 0.02 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-17 A10-04 nd -22.2481 -36.83975 251.3 16.708 35.727 4.13 0.39 0.10 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-19 A10-06 nd -14.18388 -32.65223 22.2 27.89 37.038 0.00 0.00 0.13 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-19 A10-06 nd -14.18388 -32.65223 66.5 26.657 37.19 nd 0.00 0.06 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-19 A10-06 nd -14.18388 -32.65223 101.9 24.617 37.144 0.00 0.00 0.04 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-19 A10-06 nd -14.18388 -32.65223 136.4 23.832 37.045 0.24 0.00 0.06 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-19 A10-06 nd -14.18388 -32.65223 151.6 23.27 36.934 0.29 0.13 0.14 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-19 A10-06 nd -14.18388 -32.65223 250 15.901 35.64 5.47 0.45 0.02 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-19 A10-07 nd -13.51312 -32.32762 181.6 21.681 36.677 1.13 0.23 0.14 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-19 A10-07 nd -13.51312 -32.32762 230.4 16.679 35.774 6.04 0.58 0.05 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-19 A10-07 nd -13.51312 -32.32762 296.3 12.926 35.218 16.41 1.15 0.01 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-19 A10-07 nd -13.51312 -32.32762 489.4 6.912 34.57 26.14 1.84 0.01 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-20 A10-08 nd -10.28605 -30.83139 9.6 28.581 36.429 0.00 0.01 0.19 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-20 A10-08 nd -10.28605 -30.83139 31.8 28.511 36.45 0.16 0.00 0.35 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-20 A10-08 nd -10.28605 -30.83139 55.9 27.695 36.714 0.00 0.06 0.19 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-20 A10-08 nd -10.28605 -30.83139 101 24.047 36.949 0.23 0.09 0.14 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-20 A10-08 nd -10.28605 -30.83139 119.3 22.727 36.754 0.65 0.21 0.14 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-20 A10-08 nd -10.28605 -30.83139 126.3 21.885 36.616 2.11 0.30 0.08 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-20 A10-08 nd -10.28605 -30.83139 168 16.831 35.823 12.24 0.91 0.06 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-21 A10-09 nd -6.34029 -28.9944 10.3 28.638 36.013 0.15 0.07 0.09 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-21 A10-09 nd -6.34029 -28.9944 18.4 28.619 36.013 0.14 0.04 0.13 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-21 A10-09 nd -6.34029 -28.9944 23.6 28.615 36.013 0.16 0.05 0.12 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-21 A10-09 nd -6.34029 -28.9944 33.3 28.614 36.014 0.41 0.07 0.13 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-21 A10-09 nd -6.34029 -28.9944 58.2 28.402 36.167 0.03 0.07 0.13 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-21 A10-09 nd -6.34029 -28.9944 73.5 26.953 36.544 0.17 0.04 0.09 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-21 A10-09 nd -6.34029 -28.9944 83.2 25.481 36.821 0.27 0.06 0.12 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-21 A10-09 nd -6.34029 -28.9944 107.6 21.149 36.344 2.39 0.30 0.04 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-21 A10-09 nd -6.34029 -28.9944 249.7 10.197 34.94 21.89 1.54 0.13 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-22 A10-10 nd -2.22507 -27.10071 53 22.498 35.998 0.17 0.16 0.28 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-22 A10-10 nd -2.22507 -27.10071 102.5 13.589 35.358 20.59 1.37 0.25 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-22 A10-10 nd -2.22507 -27.10071 179.2 12.791 35.246 23.01 1.54 0.40 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-22 A10-10 nd -2.22507 -27.10071 252.9 12.037 35.154 21.59 1.41 0.38 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-23 A10-11 nd 1.94233 -25.26049 10.2 28.95 35.457 0.42 0.03 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-23 A10-11 nd 1.94233 -25.26049 18.3 28.782 35.671 0.44 0.03 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-23 A10-11 nd 1.94233 -25.26049 27.1 28.386 35.733 0.47 0.00 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-23 A10-11 nd 1.94233 -25.26049 62.8 23.043 36.088 2.72 0.23 0.17 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-23 A10-11 nd 1.94233 -25.26049 73 19.597 35.908 10.97 0.71 0.54 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-23 A10-11 nd 1.94233 -25.26049 200.5 12.93 35.262 17.86 1.19 0.13 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-24 A10-12 nd 6.09809 -23.4503 9.3 28.175 35.683 0.22 0.00 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-24 A10-12 nd 6.09809 -23.4503 17.6 27.18 35.949 0.06 0.00 0.14 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-24 A10-12 nd 6.09809 -23.4503 23 26.891 35.966 0.22 0.00 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-24 A10-12 nd 6.09809 -23.4503 26.9 25.684 35.97 0.25 0.00 0.14 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-24 A10-12 nd 6.09809 -23.4503 37.2 21.464 35.957 0.25 0.11 0.16 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-24 A10-12 nd 6.09809 -23.4503 46.9 19.962 36.006 3.77 0.30 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-24 A10-12 nd 6.09809 -23.4503 56.3 18.905 35.948 6.20 0.46 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-24 A10-12 nd 6.09809 -23.4503 77.3 16.132 35.656 14.29 1.01 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-24 A10-12 nd 6.09809 -23.4503 102.1 14.841 35.506 21.12 1.40 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-25 A10-13 nd 10.20415 -21.65501 2.8 26.356 35.912 nd 0.03 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-25 A10-13 nd 10.20415 -21.65501 9.8 26.315 35.911 0.42 0.00 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-25 A10-13 nd 10.20415 -21.65501 16.9 23.011 35.848 0.00 0.00 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-25 A10-13 nd 10.20415 -21.65501 21.5 20.677 35.797 0.25 0.04 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-25 A10-13 nd 10.20415 -21.65501 33.5 17.705 35.727 1.45 0.21 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-25 A10-13 nd 10.20415 -21.65501 46.1 16.806 35.665 18.98 1.20 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-25 A10-13 nd 10.20415 -21.65501 103.7 14.414 35.46 28.08 1.59 0.11 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-25 A10-14 nd 12.46872 -20.65577 10.3 24.236 35.957 0.19 0.07 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-25 A10-14 nd 12.46872 -20.65577 50 17.461 35.764 0.34 0.18 0.16 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-25 A10-14 nd 12.46872 -20.65577 150.6 13.002 35.298 26.82 1.62 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-28 A10-15 nd 23.68236 -21.56264 10.6 20.828 36.951 0.13 0.03 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-28 A10-15 nd 23.68236 -21.56264 23.6 20.739 36.948 0.08 0.01 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-28 A10-15 nd 23.68236 -21.56264 42.4 20.714 36.946 0.05 0.07 0.11 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-28 A10-15 nd 23.68236 -21.56264 71.4 20.456 36.931 0.32 0.03 0.11 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-28 A10-15 nd 23.68236 -21.56264 77 19.803 36.86 nd 0.04 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-28 A10-15 nd 23.68236 -21.56264 81.4 19.74 36.853 0.43 0.09 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-28 A10-15 nd 23.68236 -21.56264 114.6 19.444 36.808 2.16 0.12 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-28 A10-15 nd 23.68236 -21.56264 161.4 18.082 36.516 7.21 0.39 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-29 A10-16 nd 27.53359 -21.96233 10.2 19.411 36.911 0.83 0.00 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-29 A10-16 nd 27.53359 -21.96233 17.9 19.393 36.911 0.94 0.00 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-29 A10-16 nd 27.53359 -21.96233 22.6 19.41 36.917 0.18 0.00 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-29 A10-16 nd 27.53359 -21.96233 32.8 19.41 36.917 0.19 0.00 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-29 A10-16 nd 27.53359 -21.96233 55.9 19.413 36.918 0.24 0.00 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-29 A10-16 nd 27.53359 -21.96233 82.1 19.079 36.863 0.33 0.01 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-29 A10-16 nd 27.53359 -21.96233 107.7 18.898 36.846 0.89 0.03 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-04-29 A10-16 nd 27.53359 -21.96233 172 18.241 36.718 1.30 0.06 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-01 A10-17 nd 35.9994 -19.99471 10.2 16.546 36.314 0.09 0.03 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-01 A10-17 nd 35.9994 -19.99471 18.1 16.552 36.314 0.14 0.04 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-01 A10-17 nd 35.9994 -19.99471 23.1 16.532 36.313 0.43 0.16 0.24 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-01 A10-17 nd 35.9994 -19.99471 32.9 16.47 36.31 0.43 0.03 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-01 A10-17 nd 35.9994 -19.99471 42.7 16.451 36.309 0.57 0.04 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-01 A10-17 nd 35.9994 -19.99471 53 16.452 36.308 0.72 0.07 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-01 A10-17 nd 35.9994 -19.99471 62.7 16.453 36.307 0.49 0.06 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-01 A10-17 nd 35.9994 -19.99471 76.8 16.416 36.299 0.54 0.03 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-01 A10-17 nd 35.9994 -19.99471 102.3 15.897 36.193 2.96 0.15 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-01 A10-17 nd 35.9994 -19.99471 152.1 15.16 36.06 5.16 0.28 0.11 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-01 A10-17 nd 35.9994 -19.99471 202 14.275 35.924 8.76 0.49 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-02 A10-20 nd 38.86688 -20.00355 8.9 15.201 36.03 0.43 0.03 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-02 A10-20 nd 38.86688 -20.00355 17 15.196 36.033 0.23 0.00 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-02 A10-20 nd 38.86688 -20.00355 22.5 15.201 36.035 0.34 0.02 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-02 A10-20 nd 38.86688 -20.00355 42.5 15.11 36.041 0.73 0.00 0.11 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-02 A10-20 nd 38.86688 -20.00355 61.1 15.038 36.03 1.36 0.08 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-02 A10-20 nd 38.86688 -20.00355 110.2 14.907 36.035 3.05 0.13 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-02 A10-20 nd 38.86688 -20.00355 125.3 14.771 35.997 2.96 0.13 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-02 A10-20 nd 38.86688 -20.00355 138.9 14.703 35.979 3.00 0.14 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-02 A10-20 nd 38.86688 -20.00355 198.4 14.199 35.894 6.47 0.29 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-05 A10-22 nd 48.20472 -12.83378 9.7 12.02 35.584 5.36 0.35 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-05 A10-22 nd 48.20472 -12.83378 22.4 12.019 35.584 5.41 0.34 0.20 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-05 A10-22 nd 48.20472 -12.83378 32.1 12.017 35.584 2.99 0.14 0.13 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-05 A10-22 nd 48.20472 -12.83378 51.3 11.713 35.577 4.32 0.27 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-05 A10-22 nd 48.20472 -12.83378 76 11.638 35.573 4.34 0.20 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-05 A10-22 nd 48.20472 -12.83378 98.7 11.564 35.572 7.85 0.42 0.16 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-05 A10-22 nd 48.20472 -12.83378 122.7 11.548 35.571 4.51 0.21 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-05 A10-22 nd 48.20472 -12.83378 147.9 11.533 35.57 6.96 0.40 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-06 A10-23 nd 49.31969 -6.00458 9.8 10.772 35.322 4.62 0.34 0.19 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-06 A10-23 nd 49.31969 -6.00458 17.8 10.762 35.323 5.54 0.37 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-06 A10-23 nd 49.31969 -6.00458 22.4 10.769 35.322 4.33 0.24 0.11 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-06 A10-23 nd 49.31969 -6.00458 32.1 10.763 35.323 4.95 0.24 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-06 A10-23 nd 49.31969 -6.00458 42.7 10.765 35.323 4.62 0.24 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-06 A10-23 nd 49.31969 -6.00458 52.5 10.764 35.324 6.11 0.42 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-06 A10-23 nd 49.31969 -6.00458 61.9 10.765 35.323 6.17 0.35 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT10 2000-05-06 A10-23 nd 49.31969 -6.00458 71.8 10.766 35.324 6.02 0.45 0.33 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-05-28 AMT12_32 nd -5.32086 -24.99598 0.7 28.061 35.9 0.02 0.23 0.02 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-05-28 AMT12_32 nd -5.32086 -24.99598 9.9 28.047 35.9 0.01 0.23 0.02 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-05-28 AMT12_32 nd -5.32086 -24.99598 24.5 28.039 35.961 0.02 0.19 0.04 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-05-28 AMT12_32 nd -5.32086 -24.99598 50.2 27.991 36.058 0.06 0.17 0.08 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-05-28 AMT12_32 nd -5.32086 -24.99598 74.6 27.916 36.082 0.08 0.19 0.02 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-05-28 AMT12_32 nd -5.32086 -24.99598 83.8 27.784 36.083 1.27 0.33 0.08 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-05-28 AMT12_32 nd -5.32086 -24.99598 124.5 17.166 35.789 18.35 1.24 0.02 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-05-30 AMT12_37 nd 2.21134 -26.30656 23.5 28.236 35.396 0.01 0.12 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-05-30 AMT12_37 nd 2.21134 -26.30656 48.6 27.685 35.541 0.01 0.11 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-05-30 AMT12_37 nd 2.21134 -26.30656 62.7 24.427 35.774 1.46 0.32 0.14 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-05-30 AMT12_37 nd 2.21134 -26.30656 99.2 15.991 35.608 22.56 1.43 0.11 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-05-31 AMT12_39 nd 5.91607 -28.48376 1.5 28.309 35.664 0.01 0.05 0.11 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-05-31 AMT12_39 nd 5.91607 -28.48376 9.9 28.305 35.662 0.01 0.07 0.14 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-05-31 AMT12_39 nd 5.91607 -28.48376 24.7 28.28 35.832 0.01 0.08 0.13 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-05-31 AMT12_39 nd 5.91607 -28.48376 49.2 27.678 35.845 0.07 0.09 0.14 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-05-31 AMT12_39 nd 5.91607 -28.48376 65.5 23.166 35.933 1.24 0.18 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-05-31 AMT12_39 nd 5.91607 -28.48376 99.5 16.489 35.644 18.85 1.10 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-05-31 AMT12_39 nd 5.91607 -28.48376 124.9 13.653 35.37 20.36 1.30 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-05-31 AMT12_39 nd 5.91607 -28.48376 174.5 12.215 35.181 22.73 1.49 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-01 AMT12_41 nd 9.56324 -30.67717 10.1 26.977 36.298 0.01 0.10 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-01 AMT12_41 nd 9.56324 -30.67717 59.1 22.422 36.038 11.23 0.66 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-02 AMT12_44 nd 12.23537 -32.28619 1.7 25.998 36.24 0.00 0.10 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-02 AMT12_44 nd 12.23537 -32.28619 9.1 25.985 36.24 0.03 0.13 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-02 AMT12_44 nd 12.23537 -32.28619 23.9 25.89 36.237 0.00 0.14 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-03 AMT12_46 nd 15.4484 -34.23054 1.7 24.593 36.731 0.00 0.07 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-03 AMT12_46 nd 15.4484 -34.23054 10.5 24.571 36.731 0.00 0.06 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-03 AMT12_46 nd 15.4484 -34.23054 25.7 24.464 36.764 0.00 0.04 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-03 AMT12_46 nd 15.4484 -34.23054 50.3 24.015 36.796 0.00 0.04 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-03 AMT12_46 nd 15.4484 -34.23054 75.6 23.588 36.804 0.00 0.03 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-03 AMT12_46 nd 15.4484 -34.23054 100.7 22.911 36.75 0.01 0.03 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-03 AMT12_46 nd 15.4484 -34.23054 113.9 23.022 37.028 1.37 0.09 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-03 AMT12_46 nd 15.4484 -34.23054 250.5 15.277 36.036 19.70 1.21 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-04 AMT12_48 nd 19.05075 -36.45547 2.5 24.699 36.79 0.00 0.10 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-04 AMT12_48 nd 19.05075 -36.45547 99.8 23.176 37.231 0.00 0.10 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-04 AMT12_48 nd 19.05075 -36.45547 122.7 22.271 37.2 0.12 0.10 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-04 AMT12_48 nd 19.05075 -36.45547 174.4 18.512 36.564 7.43 0.46 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-05 AMT12_50 nd 22.23174 -34.90055 2.1 24.213 37.517 0.00 0.08 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-05 AMT12_50 nd 22.23174 -34.90055 10.1 24.214 37.52 0.00 0.10 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-05 AMT12_50 nd 22.23174 -34.90055 49.8 24.057 37.502 0.00 0.09 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-05 AMT12_50 nd 22.23174 -34.90055 74.4 23.539 37.47 0.00 0.08 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-05 AMT12_50 nd 22.23174 -34.90055 124.5 21.927 37.222 0.49 0.11 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-05 AMT12_50 nd 22.23174 -34.90055 149.4 20.335 36.936 0.28 0.09 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-06 AMT12_53 nd 24.32905 -32.57326 2.2 23.648 37.424 0.01 0.06 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-06 AMT12_53 nd 24.32905 -32.57326 10.2 23.643 37.425 0.01 0.07 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-06 AMT12_53 nd 24.32905 -32.57326 25.5 23.637 37.425 0.01 0.06 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-06 AMT12_53 nd 24.32905 -32.57326 49.7 23.508 37.42 0.01 0.06 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-06 AMT12_53 nd 24.32905 -32.57326 100.1 22.703 37.406 0.01 0.05 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-06 AMT12_53 nd 24.32905 -32.57326 125.4 22.229 37.393 0.02 0.05 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-06 AMT12_53 nd 24.32905 -32.57326 150.2 21.753 37.307 0.12 0.04 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-06 AMT12_53 nd 24.32905 -32.57326 175.8 20.439 37.006 2.01 0.06 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-06 AMT12_53 nd 24.32905 -32.57326 250.4 17.646 36.472 5.83 0.29 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-07 AMT12_55 nd 27.21244 -29.29955 2 23.002 37.414 0.01 0.06 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-07 AMT12_55 nd 27.21244 -29.29955 11.9 23.001 37.415 0.00 0.08 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-07 AMT12_55 nd 27.21244 -29.29955 27.1 22.996 37.414 0.00 0.08 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-07 AMT12_55 nd 27.21244 -29.29955 51.4 22.328 37.356 0.00 0.07 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-07 AMT12_55 nd 27.21244 -29.29955 101.5 21.864 37.313 0.00 0.06 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-07 AMT12_55 nd 27.21244 -29.29955 119.8 20.866 37.117 0.03 0.06 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-07 AMT12_55 nd 27.21244 -29.29955 176.9 18.594 36.656 3.01 0.11 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-07 AMT12_55 nd 27.21244 -29.29955 251.7 16.98 36.356 7.41 0.39 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-07 AMT12_55 nd 27.21244 -29.29955 302 15.944 36.182 9.03 0.52 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-08 AMT12_57 nd 30.29099 -25.72122 10.5 21.504 36.841 0.01 0.07 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-08 AMT12_57 nd 30.29099 -25.72122 150.4 17.691 36.453 2.03 0.12 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-08 AMT12_57 nd 30.29099 -25.72122 250.2 16.122 36.217 6.73 0.38 0.14 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-09 AMT12_59 nd 33.62421 -21.71481 2 21.224 36.723 0.02 0.05 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-09 AMT12_59 nd 33.62421 -21.71481 10.5 21.093 36.721 0.02 0.05 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-09 AMT12_59 nd 33.62421 -21.71481 75.2 18.009 36.546 0.02 0.05 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-09 AMT12_59 nd 33.62421 -21.71481 94.9 17.895 36.555 0.06 0.05 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-09 AMT12_59 nd 33.62421 -21.71481 125.1 17.71 36.566 1.85 0.11 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-09 AMT12_59 nd 33.62421 -21.71481 250.3 14.99 36.037 7.00 0.45 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-11 AMT12_64 nd 41.49247 -20.02017 1.9 17.046 35.853 0.02 0.08 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-11 AMT12_64 nd 41.49247 -20.02017 17.2 16.859 35.858 0.06 0.10 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-11 AMT12_64 nd 41.49247 -20.02017 23 16.76 35.856 0.57 0.13 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-11 AMT12_64 nd 41.49247 -20.02017 48.7 14.021 35.806 2.66 0.24 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-11 AMT12_64 nd 41.49247 -20.02017 75.7 13.637 35.818 4.88 0.35 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-13 AMT12_68 nd 47.68797 -12.68195 1.4 14.255 35.623 0.04 0.10 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-13 AMT12_68 nd 47.68797 -12.68195 3.1 14.394 35.627 0.03 0.12 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-13 AMT12_68 nd 47.68797 -12.68195 22 14.171 35.623 0.13 0.13 0.51 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT12 2003-06-13 AMT12_68 nd 47.68797 -12.68195 34.7 13.781 35.633 0.20 0.19 0.39 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-04-30 AMT14_01 nd -47.03932 -50.25497 15 11.257 34.101 9.85 0.84 0.09 2 Southern Ocean UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-04-30 AMT14_01 nd -47.03932 -50.25497 20.2 11.259 34.101 9.76 0.86 0.08 2 Southern Ocean UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-04-30 AMT14_01 nd -47.03932 -50.25497 25.1 11.258 34.101 9.76 0.87 0.07 2 Southern Ocean UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-04-30 AMT14_01 nd -47.03932 -50.25497 30 11.258 34.101 9.79 0.88 0.07 2 Southern Ocean UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-02 AMT14_06 nd -41.03489 -41.55872 8.6 16.86 35.009 1.36 0.22 0.18 2 Southern Ocean UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-02 AMT14_06 nd -41.03489 -41.55872 18.6 16.86 35.008 1.25 0.23 0.02 2 Southern Ocean UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-02 AMT14_06 nd -41.03489 -41.55872 33.1 16.864 35.009 1.44 0.24 0.14 2 Southern Ocean UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-02 AMT14_06 nd -41.03489 -41.55872 65 16.237 34.974 2.21 0.26 0.13 2 Southern Ocean UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-03 AMT14_09 nd -38.88149 -38.58539 17 19.109 35.675 0.10 0.08 0.11 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-03 AMT14_09 nd -38.88149 -38.58539 27.1 19.111 35.675 0.05 0.09 0.12 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-03 AMT14_09 nd -38.88149 -38.58539 36.7 19.114 35.675 0.40 0.11 0.09 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-03 AMT14_09 nd -38.88149 -38.58539 67.2 17.87 35.862 1.70 0.28 0.03 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-04 AMT14_12 nd -35.96667 -34.78997 9.2 nd nd 0.03 0.03 0.16 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-04 AMT14_12 nd -35.96667 -34.78997 22.6 19.573 35.589 0.03 0.03 0.17 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-04 AMT14_12 nd -35.96667 -34.78997 40.7 19.566 35.601 0.03 0.07 0.07 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-04 AMT14_12 nd -35.96667 -34.78997 87.1 16.572 35.568 0.24 0.15 0.15 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-04 AMT14_12 nd -35.96667 -34.78997 120.5 15.29 35.566 4.32 0.34 0.10 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-05 AMT14_15 nd -32.97375 -31.00796 14.7 22.105 35.622 0.03 0.03 0.11 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-05 AMT14_15 nd -32.97375 -31.00796 25.2 22.112 35.623 0.03 0.03 0.22 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-05 AMT14_15 nd -32.97375 -31.00796 44.9 22.113 35.623 0.03 0.03 0.35 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-05 AMT14_15 nd -32.97375 -31.00796 101.2 18.054 35.767 0.06 0.05 0.06 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-06 AMT14_19 nd -29.76885 -27.09417 6.5 nd nd 0.03 0.01 0.08 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-06 AMT14_19 nd -29.76885 -27.09417 24.7 23.196 36.128 0.03 0.01 0.08 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-06 AMT14_19 nd -29.76885 -27.09417 44 23.2 36.129 0.03 0.01 0.15 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-06 AMT14_19 nd -29.76885 -27.09417 104.1 18.743 35.887 0.03 0.05 0.18 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-06 AMT14_19 nd -29.76885 -27.09417 153.8 16.816 35.685 0.27 0.12 0.22 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-07 AMT14_22 nd -28.08823 -25.10199 24.3 23.819 36.356 0.03 0.00 0.09 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-07 AMT14_22 nd -28.08823 -25.10199 123.7 18.604 35.888 0.11 0.05 0.08 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-07 AMT14_22 nd -28.08823 -25.10199 157.7 17.243 35.752 1.40 0.17 0.08 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-08 AMT14_26 nd -24.23124 -24.99512 15 25.16 36.87 0.03 0.02 0.09 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-08 AMT14_26 nd -24.23124 -24.99512 26 25.162 36.871 0.03 0.02 0.15 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-08 AMT14_26 nd -24.23124 -24.99512 47.6 25.109 36.995 0.03 0.03 0.16 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-08 AMT14_26 nd -24.23124 -24.99512 120.3 20.157 36.242 0.23 0.07 0.14 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-08 AMT14_26 nd -24.23124 -24.99512 164.7 17.563 35.829 1.42 0.12 0.20 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-09 AMT14_30 nd -20.92963 -25.00379 20.2 25.599 37.239 0.26 0.11 0.19 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-09 AMT14_30 nd -20.92963 -25.00379 35.8 25.59 37.236 0.04 0.10 0.23 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-09 AMT14_30 nd -20.92963 -25.00379 64.2 25.578 37.243 0.05 0.10 0.25 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-10 AMT14_33 nd -16.64452 -24.99619 19.4 25.585 37.282 0.03 0.09 0.26 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-10 AMT14_33 nd -16.64452 -24.99619 35.4 25.592 37.282 0.03 0.09 0.26 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-10 AMT14_33 nd -16.64452 -24.99619 64.2 25.597 37.282 0.03 0.09 0.27 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-10 AMT14_33 nd -16.64452 -24.99619 149.4 20.883 36.459 0.32 0.11 0.24 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-10 AMT14_33 nd -16.64452 -24.99619 224.3 15.296 35.528 9.68 0.56 0.19 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-11 AMT14_36 nd -12.27593 -24.99443 129.7 21.653 36.583 3.80 0.20 0.14 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-12 AMT14_38 nd -8.81756 -25.00206 13.7 27.907 36.354 0.06 0.03 0.22 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-12 AMT14_38 nd -8.81756 -25.00206 24.9 27.915 36.354 0.05 0.03 0.22 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-12 AMT14_38 nd -8.81756 -25.00206 45.7 27.913 36.353 0.06 0.03 0.21 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-12 AMT14_38 nd -8.81756 -25.00206 102 23.686 36.648 0.42 0.06 0.37 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-12 AMT14_38 nd -8.81756 -25.00206 153.1 17.59 35.902 16.88 0.80 0.33 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-13 AMT14_41 nd -4.46185 -25.01249 11.8 27.955 36.112 0.03 0.03 0.25 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-13 AMT14_41 nd -4.46185 -25.01249 21.5 27.958 36.112 0.03 0.03 0.24 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-13 AMT14_41 nd -4.46185 -25.01249 39.2 27.962 36.112 0.03 0.03 0.24 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-13 AMT14_41 nd -4.46185 -25.01249 89.8 23.044 36.218 1.71 0.14 0.37 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-13 AMT14_41 nd -4.46185 -25.01249 137 15.266 35.589 20.34 1.00 0.26 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-14 AMT14_44 nd -0.10135 -24.99662 8 27.296 36.3 0.03 0.03 0.48 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-14 AMT14_44 nd -0.10135 -24.99662 15 27.306 36.3 0.03 0.03 0.49 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-14 AMT14_44 nd -0.10135 -24.99662 26.8 27.126 36.323 0.03 0.03 0.18 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-14 AMT14_44 nd -0.10135 -24.99662 59.1 24.337 36.572 3.48 0.13 0.32 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-14 AMT14_44 nd -0.10135 -24.99662 91.7 17.098 35.863 10.71 0.60 0.22 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-15 AMT14_47 nd 3.24473 -26.24346 6.4 28.34 34.893 0.06 0.03 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-15 AMT14_47 nd 3.24473 -26.24346 11.3 28.48 35.085 0.03 0.03 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-15 AMT14_47 nd 3.24473 -26.24346 21.6 28.484 35.403 0.03 0.03 0.16 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-15 AMT14_47 nd 3.24473 -26.24346 48.8 27.186 35.823 0.05 0.03 0.14 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-15 AMT14_47 nd 3.24473 -26.24346 74.8 17.422 35.711 21.29 1.00 0.23 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-16 AMT14_50 nd 7.28897 -27.78171 8 27.176 35.601 0.04 0.03 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-16 AMT14_50 nd 7.28897 -27.78171 15 27.18 35.601 0.04 0.03 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-16 AMT14_50 nd 7.28897 -27.78171 25.9 27.182 35.607 0.03 0.03 0.13 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-16 AMT14_50 nd 7.28897 -27.78171 59.8 19.727 35.928 9.28 0.37 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-16 AMT14_50 nd 7.28897 -27.78171 75.5 16.157 35.679 25.79 1.18 0.28 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-17 AMT14_53 nd 11.40053 -29.36786 18.5 25.666 36.196 0.03 0.03 0.14 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-17 AMT14_53 nd 11.40053 -29.36786 33.8 25.669 36.196 0.03 0.03 0.14 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-17 AMT14_53 nd 11.40053 -29.36786 79.9 18.127 35.767 22.48 1.14 0.18 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-18 AMT14_56 nd 14.75553 -30.68309 13 23.923 36.359 0.03 0.03 0.16 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-18 AMT14_56 nd 14.75553 -30.68309 24.4 23.921 36.36 0.03 0.03 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-18 AMT14_56 nd 14.75553 -30.68309 44 23.815 36.391 0.03 0.03 0.19 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-18 AMT14_56 nd 14.75553 -30.68309 100.2 21.952 36.879 9.44 0.41 0.13 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-18 AMT14_56 nd 14.75553 -30.68309 150.5 16.767 36.215 23.19 1.05 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-19 AMT14_59 nd 18.79636 -32.28879 15.6 23.608 36.566 0.03 0.03 0.17 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-19 AMT14_59 nd 18.79636 -32.28879 29.9 23.585 36.564 0.03 0.03 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-19 AMT14_59 nd 18.79636 -32.28879 53.4 23.555 36.684 0.03 0.03 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-19 AMT14_59 nd 18.79636 -32.28879 187.8 18.574 36.617 9.87 0.47 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-20 AMT14_63 nd 22.33456 -33.73347 14.6 23.744 37.503 0.03 0.01 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-20 AMT14_63 nd 22.33456 -33.73347 27.9 23.631 37.497 0.03 0.01 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-20 AMT14_63 nd 22.33456 -33.73347 49.5 23.435 37.494 0.03 0.01 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-20 AMT14_63 nd 22.33456 -33.73347 114.5 21.138 37.071 0.74 0.02 0.11 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-20 AMT14_63 nd 22.33456 -33.73347 172 18.879 36.685 5.63 0.22 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-21 AMT14_67 nd 25.92199 -35.23629 16.9 37.31 22.43 0.03 0.00 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-21 AMT14_67 nd 25.92199 -35.23629 31.1 37.308 22.349 0.03 0.00 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-21 AMT14_67 nd 25.92199 -35.23629 56 37.267 22.187 0.03 0.00 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-21 AMT14_67 nd 25.92199 -35.23629 129.9 37.064 20.995 0.05 0.00 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-21 AMT14_67 nd 25.92199 -35.23629 195.2 36.622 18.687 4.08 0.07 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-22 AMT14_71 nd 29.30054 -36.69945 17.1 20.772 36.94 0.03 0.00 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-22 AMT14_71 nd 29.30054 -36.69945 31.6 20.774 36.94 0.03 0.00 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-22 AMT14_71 nd 29.30054 -36.69945 56.2 20.478 36.914 0.03 0.00 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-22 AMT14_71 nd 29.30054 -36.69945 130.4 19.55 36.818 0.14 0.01 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-22 AMT14_71 nd 29.30054 -36.69945 195.9 17.983 36.509 4.28 0.18 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-23 AMT14_75 nd 31.93115 -31.17635 99.3 18.854 36.628 0.03 0.01 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-23 AMT14_75 nd 31.93115 -31.17635 179.2 18.013 36.545 4.04 0.09 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-25 AMT14_77 nd 35.747 -22.85163 10.2 18.86 36.459 0.03 0.00 0.22 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-25 AMT14_77 nd 35.747 -22.85163 19.3 18.829 36.457 0.03 0.00 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-25 AMT14_77 nd 35.747 -22.85163 34.9 17.695 36.33 0.03 0.00 0.24 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-25 AMT14_77 nd 35.747 -22.85163 89.3 16.947 36.292 0.83 0.03 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-25 AMT14_77 nd 35.747 -22.85163 129.5 16.169 36.2 2.98 0.06 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-26 AMT14_80 nd 38.66634 -19.96059 12.8 16.529 36.149 nd nd 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-26 AMT14_80 nd 38.66634 -19.96059 24 16.215 36.108 0.08 0.00 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-26 AMT14_80 nd 38.66634 -19.96059 49.8 15.486 36.095 1.09 0.02 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-26 AMT14_80 nd 38.66634 -19.96059 80.6 15.126 36.055 3.29 0.07 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-27 AMT14_83 nd 41.98623 -18.79265 7.7 15.846 36.01 0.03 0.01 0.22 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-27 AMT14_83 nd 41.98623 -18.79265 20.8 15.497 36.014 0.03 0.01 0.14 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-27 AMT14_83 nd 41.98623 -18.79265 36.7 14.861 36.018 0.03 0.02 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-27 AMT14_83 nd 41.98623 -18.79265 71.1 14.628 35.981 1.68 0.06 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-28 AMT14_86 nd 47.81141 -16.77694 9.8 13.204 35.737 4.19 0.17 0.17 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-28 AMT14_86 nd 47.81141 -16.77694 22.7 13.205 35.737 4.28 0.21 0.11 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-28 AMT14_86 nd 47.81141 -16.77694 43.2 13.113 35.734 4.54 0.25 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-29 AMT14_88 nd 48.99986 -16.39474 7.8 13.278 35.664 5.68 0.32 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-29 AMT14_88 nd 48.99986 -16.39474 15 13.282 35.666 5.72 0.33 0.13 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-29 AMT14_88 nd 48.99986 -16.39474 27.4 13.282 35.667 5.83 0.35 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-29 AMT14_88 nd 48.99986 -16.39474 61.1 12.113 35.618 7.78 0.49 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT14 2004-05-29 AMT14_88 nd 48.99986 -16.39474 91.2 11.989 35.617 8.24 0.55 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-09-21 4 nd 47.92336 -14.61 12.4 16.505 35.666 0.10 0.18 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-09-21 4 nd 47.92336 -14.61 35.9 16.508 35.666 0.12 0.12 0.55 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-09-22 6 nd 45.98198 -18.39411 27.3 18.513 35.936 0.03 0.03 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-09-23 6 nd 42.55828 -19.8356 11.8 19.869 35.976 0.03 0.03 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-09-23 6 nd 42.55828 -19.8356 16.9 19.873 35.976 0.03 0.03 0.23 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-09-23 6 nd 42.55828 -19.8356 31.6 19.879 35.976 0.03 0.03 0.20 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-09-23 6 nd 42.55828 -19.8356 51.7 18.935 35.932 2.56 0.03 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-09-25 12 nd 35.09471 -20.8471 16.9 23.969 36.668 0.03 0.01 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-09-25 12 nd 35.09471 -20.8471 26.3 23.952 36.668 0.03 0.00 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-09-25 12 nd 35.09471 -20.8471 52 19.374 36.295 0.03 0.00 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-09-25 12 nd 35.09471 -20.8471 87.4 17.35 36.308 0.27 0.03 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-09-25 12 nd 35.09471 -20.8471 151.6 15.97 36.179 5.75 0.27 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-09-26 14 nd 31.25788 -20.72007 16.6 24.723 37.281 0.03 0.00 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-09-26 14 nd 31.25788 -20.72007 117 18.414 36.596 4.03 0.18 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-09-27 16 nd 29.12373 -16.96941 15.5 24.352 36.982 0.03 0.03 0.11 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-09-27 16 nd 29.12373 -16.96941 30.1 24.394 37.021 0.03 0.03 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-09-27 16 nd 29.12373 -16.96941 56.1 22.789 36.882 0.03 0.03 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-09-27 16 nd 29.12373 -16.96941 116.8 18.345 36.673 0.30 0.03 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-09-27 16 nd 29.12373 -16.96941 180.6 17.101 36.455 2.97 0.15 0.11 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-09-29 18 nd 23.55763 -19.99271 11.6 25.065 36.844 0.03 0.02 0.18 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-09-29 18 nd 23.55763 -19.99271 16.1 25.066 36.844 0.03 0.02 0.17 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-09-29 18 nd 23.55763 -19.99271 26.3 25.055 36.844 0.03 0.03 0.17 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-09-29 18 nd 23.55763 -19.99271 51.2 22.612 36.56 1.31 0.20 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-09-29 18 nd 23.55763 -19.99271 73.2 19.745 36.723 5.05 0.35 0.11 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-09-30 20 nd 21.37678 -18.83547 4.5 23.397 36.211 0.07 0.25 0.20 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-09-30 20 nd 21.37678 -18.83547 7.7 23.392 36.211 0.06 0.27 0.21 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-09-30 20 nd 21.37678 -18.83547 17.3 23.373 36.21 0.03 0.30 0.21 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-09-30 20 nd 21.37678 -18.83547 32.3 23.479 36.333 0.07 0.31 0.21 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-09-30 20 nd 21.37678 -18.83547 52.5 21.331 36.56 3.63 0.30 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-01 23 nd 21.6936 -17.8272 26.8 21.139 36.054 7.86 0.75 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-02 26 nd 21.35465 -17.37257 7 19.771 36.071 9.56 0.65 0.58 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-02 26 nd 21.35465 -17.37257 11.9 18.86 35.999 15.03 1.03 0.30 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-02 26 nd 21.35465 -17.37257 17.1 18.254 35.953 17.09 1.15 0.14 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-03 29 nd 21.30735 -18.59319 21.7 23.082 36.124 0.18 0.15 0.36 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-03 29 nd 21.30735 -18.59319 31.7 22.551 36.101 0.73 0.27 0.14 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-04 30 nd 17.83822 -20.89145 11.2 26.701 36.401 0.03 0.06 0.20 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-04 30 nd 17.83822 -20.89145 30.3 26.705 36.401 0.03 0.09 0.20 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-04 30 nd 17.83822 -20.89145 70.5 19.186 36.373 12.52 0.91 0.24 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-04 30 nd 17.83822 -20.89145 101.3 16.392 36.012 23.02 1.29 0.13 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-05 32 nd 14.29584 -21.7599 1.9 28.186 35.916 0.03 0.02 0.18 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-05 32 nd 14.29584 -21.7599 10.7 28.18 35.913 0.03 0.02 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-05 32 nd 14.29584 -21.7599 50.9 21.097 36.347 1.60 0.27 0.19 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-05 32 nd 14.29584 -21.7599 75.9 17.957 36.065 19.00 1.07 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-06 34 nd 11.00187 -22.51456 11.4 28.934 35.383 0.03 0.00 0.17 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-06 34 nd 11.00187 -22.51456 17.2 28.937 35.384 0.03 0.00 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-06 34 nd 11.00187 -22.51456 26.3 27.324 35.884 0.03 0.00 0.16 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-06 34 nd 11.00187 -22.51456 62.1 18.626 35.8 13.62 0.79 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-07 36 nd 7.86131 -23.23139 12.3 28.902 35.526 0.03 0.00 0.16 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-07 36 nd 7.86131 -23.23139 16.5 28.587 35.574 0.03 0.00 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-07 36 nd 7.86131 -23.23139 26.2 28.029 35.696 0.03 0.01 0.14 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-07 36 nd 7.86131 -23.23139 61.2 19.31 35.925 15.13 0.78 0.26 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-07 36 nd 7.86131 -23.23139 81.5 16.177 35.679 19.72 1.18 0.16 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-08 38 nd 4.76579 -23.90881 11.5 28.136 34.437 0.03 0.01 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-08 38 nd 4.76579 -23.90881 21 28.218 34.514 0.03 0.00 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-08 38 nd 4.76579 -23.90881 74.9 20.601 35.983 10.96 0.46 0.29 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-08 38 nd 4.76579 -23.90881 110.4 14.932 35.524 23.72 1.32 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-09 39 nd 2.51022 -24.435 12 27.858 35.447 0.03 0.00 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-09 39 nd 2.51022 -24.435 22.4 27.858 35.451 0.03 0.01 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-09 39 nd 2.51022 -24.435 31.4 27.842 35.464 0.03 0.01 0.14 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-09 39 nd 2.51022 -24.435 75 23.721 35.929 2.56 0.24 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-10 41 nd 0.06784 -24.97374 10.4 26.462 36.066 0.03 0.05 0.16 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-10 41 nd 0.06784 -24.97374 15.5 26.465 36.066 0.03 0.05 0.17 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-10 41 nd 0.06784 -24.97374 65.7 25.78 36.142 1.46 0.08 0.23 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-10 41 nd 0.06784 -24.97374 99.8 22.82 36.474 3.95 0.28 0.21 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-12 44 nd -6.8467 -25.01279 47.8 25.847 36.231 0.03 0.10 0.19 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-12 44 nd -6.8467 -25.01279 101.2 22.418 36.604 0.55 0.25 0.02 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-13 46 nd -10.40847 -24.99297 31.1 25.367 36.403 0.03 0.09 0.17 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-13 46 nd -10.40847 -24.99297 56.3 25.371 36.404 0.03 0.09 0.10 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-13 46 nd -10.40847 -24.99297 181.3 16.511 35.764 11.41 0.79 0.10 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-14 48 nd -14.17693 -24.9905 21.3 24.639 37.01 0.03 0.08 0.09 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-14 48 nd -14.17693 -24.9905 36.3 24.258 37.092 0.03 0.11 0.15 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-14 48 nd -14.17693 -24.9905 61.3 24.123 37.088 0.03 0.13 0.14 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-14 48 nd -14.17693 -24.9905 141.1 19.833 36.302 2.43 0.40 0.04 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-14 48 nd -14.17693 -24.9905 201.4 15.286 35.532 8.09 0.68 0.04 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-15 50 nd -17.94819 -24.99475 26.9 23.769 37.181 0.03 0.14 0.17 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-15 50 nd -17.94819 -24.99475 46.2 23.747 37.176 0.03 0.14 0.15 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-15 50 nd -17.94819 -24.99475 81.3 23.636 37.157 0.03 0.14 0.14 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-15 50 nd -17.94819 -24.99475 174 20.326 36.422 0.75 0.22 0.11 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-15 50 nd -17.94819 -24.99475 253.2 15.128 35.496 8.67 0.62 0.06 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-16 52 nd -20.63716 -23.66898 24.2 23.289 37.058 0.03 0.14 0.16 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-16 52 nd -20.63716 -23.66898 44.4 23.29 37.06 0.03 0.14 0.16 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-16 52 nd -20.63716 -23.66898 79.6 23.192 37.055 0.03 0.15 0.16 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-16 52 nd -20.63716 -23.66898 169.5 20.438 36.444 0.46 0.17 0.16 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-18 56 nd -23.56162 -17.49831 88 21.629 36.707 0.03 0.18 0.06 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-18 56 nd -23.56162 -17.49831 182.5 18.366 36.017 1.75 0.33 0.02 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-18 56 nd -23.56162 -17.49831 278 13.76 35.285 10.00 0.76 0.02 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-19 58 nd -25.23409 -13.91123 22.1 20.874 36.523 0.03 0.13 0.12 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-19 58 nd -25.23409 -13.91123 41.7 20.876 36.522 0.03 0.13 0.16 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-19 58 nd -25.23409 -13.91123 71.4 20.842 36.517 0.03 0.15 0.13 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-19 58 nd -25.23409 -13.91123 150.4 18.429 35.997 0.98 0.25 0.11 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-19 58 nd -25.23409 -13.91123 202.1 15.965 35.592 4.00 0.41 0.08 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-20 60 nd -26.87763 -10.33284 22.5 19.577 36.243 0.03 0.16 0.14 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-20 60 nd -26.87763 -10.33284 37.1 19.576 36.243 0.03 0.18 0.13 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-20 60 nd -26.87763 -10.33284 62.2 19.563 36.252 0.03 0.18 0.13 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-20 60 nd -26.87763 -10.33284 151.7 18.089 35.912 0.45 0.22 0.09 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-20 60 nd -26.87763 -10.33284 221.8 15.319 35.48 5.39 0.51 0.04 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-21 62 nd -28.58019 -6.56848 17.4 18.685 36.014 0.03 0.16 0.15 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-21 62 nd -28.58019 -6.56848 26.6 18.662 36.013 0.03 0.16 0.11 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-21 62 nd -28.58019 -6.56848 51.9 18.441 35.999 0.03 0.17 0.14 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-21 62 nd -28.58019 -6.56848 112.4 17.209 35.739 3.56 0.35 0.11 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-21 62 nd -28.58019 -6.56848 161.7 14.557 35.319 9.11 0.66 0.02 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-23 66 nd -34.52173 -1.37466 36.7 15.785 35.367 0.03 0.17 0.09 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-23 66 nd -34.52173 -1.37466 86.3 15.271 35.307 0.22 0.20 0.11 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-23 66 nd -34.52173 -1.37466 121.9 14.763 35.225 0.60 0.25 0.08 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-24 68 nd -37.83334 1.23434 6.9 13.707 34.802 2.78 0.36 0.14 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-24 68 nd -37.83334 1.23434 12.7 13.71 34.802 2.73 0.34 0.17 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-24 68 nd -37.83334 1.23434 22.8 13.706 34.802 2.70 0.35 0.16 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-24 68 nd -37.83334 1.23434 43 13.373 34.865 2.35 0.33 0.16 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-24 68 nd -37.83334 1.23434 73.2 13.323 34.869 2.54 0.36 0.10 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-25 70 nd -40.00273 5.01506 12.1 11.095 34.471 8.30 0.75 0.07 2 Southern Ocean UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-25 70 nd -40.00273 5.01506 21.8 11.103 34.471 8.40 0.76 0.05 2 Southern Ocean UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT15 2004-10-25 70 nd -40.00273 5.01506 46.7 10.465 34.441 9.22 0.83 0.07 2 Southern Ocean UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-19 3 nd 46.22974 -17.44212 2 17.151 35.868 0.01 0.04 0.30 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-19 3 nd 46.22974 -17.44212 14.9 17.133 35.867 0.01 0.05 0.26 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-19 3 nd 46.22974 -17.44212 26.8 17.138 35.867 0.01 0.05 0.25 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-19 3 nd 46.22974 -17.44212 48.9 17.141 35.867 0.14 0.07 0.22 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-19 3 nd 46.22974 -17.44212 57.5 15.376 35.977 3.73 0.13 0.18 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-19 3 nd 46.22974 -17.44212 71.4 15.146 36.031 5.87 0.27 0.17 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-19 3 nd 46.22974 -17.44212 110.9 14.463 35.921 7.14 0.38 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-19 3 nd 46.22974 -17.44212 165.5 13.464 35.75 8.29 0.49 0.14 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-19 3 nd 46.22974 -17.44212 201 13.117 35.718 9.37 0.57 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-19 3 nd 46.22974 -17.44212 302.8 12.402 35.669 10.22 0.65 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-20 4 nd 44.34735 -19.33307 1.2 18.529 35.966 0.01 0.03 0.34 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-20 4 nd 44.34735 -19.33307 4.8 18.53 35.966 0.01 0.03 0.31 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-20 4 nd 44.34735 -19.33307 10.6 18.527 35.966 0.00 0.03 0.27 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-20 4 nd 44.34735 -19.33307 20 18.525 35.966 0.00 0.03 0.26 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-20 4 nd 44.34735 -19.33307 40.2 17.746 35.951 0.00 0.03 0.26 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-20 4 nd 44.34735 -19.33307 45.3 15.759 35.947 0.00 0.04 0.25 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-20 4 nd 44.34735 -19.33307 46.9 15.669 35.958 0.32 0.10 0.19 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-20 4 nd 44.34735 -19.33307 58.2 15.129 35.942 2.87 0.12 0.18 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-20 4 nd 44.34735 -19.33307 70.3 14.969 35.988 5.31 0.24 0.14 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-20 4 nd 44.34735 -19.33307 98.1 14.727 35.971 6.25 0.32 0.11 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-20 4 nd 44.34735 -19.33307 198.2 13.468 35.794 8.75 0.48 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-20 4 nd 44.34735 -19.33307 299.2 12.914 35.752 9.24 0.55 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-28 7 nd 35.92254 -29.13092 12.2 21.758 36.423 0.01 0.01 0.20 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-28 7 nd 35.92254 -29.13092 22.9 21.759 36.423 0.01 0.01 0.18 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-28 7 nd 35.92254 -29.13092 40.9 21.76 36.423 0.01 0.01 0.16 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-28 7 nd 35.92254 -29.13092 79.9 19.08 36.328 0.01 0.01 0.13 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-28 7 nd 35.92254 -29.13092 84.6 18.496 36.306 0.04 0.02 0.11 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-28 7 nd 35.92254 -29.13092 104.1 17.412 36.281 3.80 0.13 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-28 7 nd 35.92254 -29.13092 141 16.194 36.223 4.78 0.22 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-28 7 nd 35.92254 -29.13092 201 15.217 36.097 6.55 0.35 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-28 7 nd 35.92254 -29.13092 300.1 13.868 35.865 10.02 0.57 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-30 9 nd 31.29968 -32.04818 23.3 23.7 36.784 0.01 0.01 0.24 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-30 9 nd 31.29968 -32.04818 43.4 23.701 36.784 0.01 0.01 0.20 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-30 9 nd 31.29968 -32.04818 68.6 20.614 36.621 0.01 0.01 0.18 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-30 9 nd 31.29968 -32.04818 78.9 19.734 36.592 0.01 0.02 0.16 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-30 9 nd 31.29968 -32.04818 88.9 19.223 36.585 0.01 0.01 0.14 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-30 9 nd 31.29968 -32.04818 99.7 18.734 36.564 0.20 0.02 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-30 9 nd 31.29968 -32.04818 117.6 18.509 36.561 1.17 0.06 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-30 9 nd 31.29968 -32.04818 149.3 18.111 36.541 3.37 0.18 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-30 9 nd 31.29968 -32.04818 198.5 17.746 36.482 4.33 0.15 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-30 9 nd 31.29968 -32.04818 298.7 16.774 36.32 6.24 0.28 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-31 11 nd 29.52611 -36.27322 13.1 24.596 36.941 0.00 0.00 0.26 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-31 11 nd 29.52611 -36.27322 23.4 24.603 36.943 0.00 0.00 0.25 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-31 11 nd 29.52611 -36.27322 44 22.395 36.642 0.00 0.00 0.25 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-31 11 nd 29.52611 -36.27322 79.6 19.82 36.607 0.00 0.00 0.21 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-31 11 nd 29.52611 -36.27322 91 19.337 36.593 0.01 0.01 0.19 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-31 11 nd 29.52611 -36.27322 100.1 18.972 36.592 0.11 0.01 0.17 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-31 11 nd 29.52611 -36.27322 120 18.677 36.582 0.88 0.04 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-31 11 nd 29.52611 -36.27322 151.8 18.208 36.546 2.96 0.15 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-31 11 nd 29.52611 -36.27322 201.3 17.784 36.512 4.12 0.21 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-10-31 11 nd 29.52611 -36.27322 300.6 16.357 36.254 7.11 0.33 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-01 13 nd 27.78194 -38.80805 15.5 25.322 37.259 0.00 0.00 0.26 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-01 13 nd 27.78194 -38.80805 28.8 25.326 37.259 0.00 0.00 0.26 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-01 13 nd 27.78194 -38.80805 50.9 25.297 37.25 0.00 0.00 0.23 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-01 13 nd 27.78194 -38.80805 101.1 19.856 36.715 0.00 0.01 0.21 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-01 13 nd 27.78194 -38.80805 111.1 19.59 36.681 0.00 0.01 0.21 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-01 13 nd 27.78194 -38.80805 115.9 19.385 36.662 0.00 0.01 0.18 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-01 13 nd 27.78194 -38.80805 125.7 19.157 36.667 0.30 0.02 0.16 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-01 13 nd 27.78194 -38.80805 174 18.213 36.55 3.46 0.11 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-01 13 nd 27.78194 -38.80805 201.5 17.871 36.506 4.37 0.16 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-01 13 nd 27.78194 -38.80805 300.6 16.411 36.268 7.12 0.34 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-02 15 nd 23.96198 -36.77857 26.9 26.438 37.421 0.01 0.01 0.18 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-02 15 nd 23.96198 -36.77857 47.9 26.427 37.422 0.01 0.01 0.19 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-02 15 nd 23.96198 -36.77857 85.7 23.931 37.311 0.01 0.01 0.17 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-02 15 nd 23.96198 -36.77857 96 22.832 37.171 0.01 0.01 0.16 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-02 15 nd 23.96198 -36.77857 100.8 22.506 37.15 0.02 0.01 0.14 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-02 15 nd 23.96198 -36.77857 105.7 22.218 37.139 0.08 0.02 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-02 15 nd 23.96198 -36.77857 114 21.696 37.043 0.12 0.02 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-02 15 nd 23.96198 -36.77857 161.6 19.788 36.768 1.29 0.05 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-02 15 nd 23.96198 -36.77857 202.1 18.455 36.592 3.89 0.13 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-02 15 nd 23.96198 -36.77857 300.8 16.746 36.324 7.07 0.32 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-03 18 nd 21.05351 -35.27266 17.9 26.557 37.492 0.01 0.01 0.20 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-03 18 nd 21.05351 -35.27266 30.9 26.56 37.492 0.00 0.01 0.19 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-03 18 nd 21.05351 -35.27266 57.8 26.515 37.499 0.00 0.01 0.19 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-03 18 nd 21.05351 -35.27266 91.8 23.642 37.359 0.01 0.01 0.18 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-03 18 nd 21.05351 -35.27266 110.3 22.822 37.333 0.01 0.01 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-03 18 nd 21.05351 -35.27266 120.5 22.68 37.322 0.01 0.01 0.16 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-03 18 nd 21.05351 -35.27266 127.1 22.362 37.294 0.10 0.02 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-03 18 nd 21.05351 -35.27266 135.7 21.901 37.256 0.42 0.04 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-03 18 nd 21.05351 -35.27266 195.2 20.508 37.107 2.88 0.10 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-03 18 nd 21.05351 -35.27266 300.6 15.878 36.145 9.52 0.73 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-04 20 nd 18.37798 -33.91454 15.9 26.955 37.199 0.01 0.01 0.17 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-04 20 nd 18.37798 -33.91454 53.3 26.232 37.433 0.01 0.01 0.17 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-04 20 nd 18.37798 -33.91454 89.5 23.333 37.352 0.01 0.01 0.17 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-04 20 nd 18.37798 -33.91454 98.7 23.032 37.327 0.01 0.01 0.17 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-04 20 nd 18.37798 -33.91454 110.3 22.39 37.273 0.02 0.02 0.16 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-04 20 nd 18.37798 -33.91454 114.1 22.246 37.26 0.11 0.03 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-04 20 nd 18.37798 -33.91454 129.1 21.42 37.153 0.93 0.06 0.13 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-04 20 nd 18.37798 -33.91454 184.7 18.942 36.729 6.05 0.27 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-04 20 nd 18.37798 -33.91454 297.4 15.018 35.987 10.02 0.94 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-05 22 nd 15.12522 -32.2964 1.4 27.551 36.287 0.01 0.01 0.21 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-05 22 nd 15.12522 -32.2964 11.2 27.558 36.287 0.01 0.01 0.20 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-05 22 nd 15.12522 -32.2964 20.1 27.563 36.287 0.01 0.01 0.18 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-05 22 nd 15.12522 -32.2964 37 27.568 36.287 0.01 0.01 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-05 22 nd 15.12522 -32.2964 70.6 22.789 37.086 0.01 0.05 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-05 22 nd 15.12522 -32.2964 81.3 21.888 37.018 2.98 0.18 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-05 22 nd 15.12522 -32.2964 84.5 21.517 36.977 4.84 0.27 0.11 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-05 22 nd 15.12522 -32.2964 90.9 20.388 36.769 6.91 0.42 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-05 22 nd 15.12522 -32.2964 126.3 17.192 36.268 15.20 0.87 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-05 22 nd 15.12522 -32.2964 199.8 13.977 35.735 23.64 1.05 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-05 22 nd 15.12522 -32.2964 298.8 11.541 35.393 26.63 1.68 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-06 24 nd 12.06969 -30.80251 3.8 27.499 35.918 0.01 0.01 0.16 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-06 24 nd 12.06969 -30.80251 8.4 27.496 35.918 0.01 0.01 0.16 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-06 24 nd 12.06969 -30.80251 16.8 27.499 35.918 0.01 0.02 0.14 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-06 24 nd 12.06969 -30.80251 29.5 27.004 36 0.00 0.03 0.11 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-06 24 nd 12.06969 -30.80251 34.6 22.144 35.977 0.01 0.07 0.14 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-06 24 nd 12.06969 -30.80251 40.2 19.718 35.876 2.73 0.19 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-06 24 nd 12.06969 -30.80251 44.9 18.478 35.824 11.93 0.72 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-06 24 nd 12.06969 -30.80251 60.2 16.238 35.675 22.50 1.37 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-06 24 nd 12.06969 -30.80251 100.2 13.391 35.393 23.87 1.63 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-06 24 nd 12.06969 -30.80251 200 11.194 35.112 27.55 1.83 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-06 24 nd 12.06969 -30.80251 300.7 10.574 35.092 23.87 2.01 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-07 26 nd 9.43397 -29.52006 7.5 28.121 35.347 0.00 0.01 0.26 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-07 26 nd 9.43397 -29.52006 14 28.111 35.348 0.00 0.01 0.25 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-07 26 nd 9.43397 -29.52006 25.6 28.128 35.357 0.00 0.01 0.20 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-07 26 nd 9.43397 -29.52006 48.5 26.471 36.268 0.01 0.03 0.18 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-07 26 nd 9.43397 -29.52006 58.3 24.439 36.27 0.14 0.05 0.16 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-07 26 nd 9.43397 -29.52006 59.2 24.144 36.256 0.92 0.09 0.14 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-07 26 nd 9.43397 -29.52006 68.5 22.21 36.137 3.32 0.18 0.13 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-07 26 nd 9.43397 -29.52006 88.5 18.967 35.976 13.62 0.72 0.11 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-07 26 nd 9.43397 -29.52006 198.3 11.331 35.117 26.50 1.67 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-07 26 nd 9.43397 -29.52006 298.3 10.227 34.999 29.74 1.96 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-08 29 nd 6.50656 -28.11006 4.7 28.185 34.754 0.00 0.01 0.24 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-08 29 nd 6.50656 -28.11006 11.6 28.311 34.863 0.00 0.01 0.19 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-08 29 nd 6.50656 -28.11006 20.8 28.92 35.55 0.00 0.01 0.19 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-08 29 nd 6.50656 -28.11006 39.9 28.059 36.026 0.01 0.03 0.16 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-08 29 nd 6.50656 -28.11006 43.5 27.798 36.086 0.01 0.03 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-08 29 nd 6.50656 -28.11006 47 27.504 36.134 0.02 0.04 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-08 29 nd 6.50656 -28.11006 59.8 25.708 36.253 1.10 0.12 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-08 29 nd 6.50656 -28.11006 71.8 24.294 36.273 4.39 0.18 0.11 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-08 29 nd 6.50656 -28.11006 200.5 11.625 35.135 23.04 1.43 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-08 29 nd 6.50656 -28.11006 299.7 10.035 34.948 27.85 1.85 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-09 32 nd 3.4764 -26.65992 9.9 28.131 35.48 0.00 0.03 0.28 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-09 32 nd 3.4764 -26.65992 18.8 28.127 35.477 0.01 0.03 0.26 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-09 32 nd 3.4764 -26.65992 34 28.349 35.842 0.00 0.04 0.24 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-09 32 nd 3.4764 -26.65992 54.5 27.832 35.795 0.01 0.04 0.20 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-09 32 nd 3.4764 -26.65992 73.4 27.357 36.016 0.01 0.07 0.18 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-09 32 nd 3.4764 -26.65992 77.5 27.156 36.057 0.01 0.08 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-09 32 nd 3.4764 -26.65992 80.8 27.15 36.039 0.25 0.11 0.17 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-09 32 nd 3.4764 -26.65992 89.2 22.487 35.91 7.01 0.40 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-09 32 nd 3.4764 -26.65992 116.7 16.154 35.62 19.74 1.22 0.11 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-09 32 nd 3.4764 -26.65992 198.8 13.572 35.354 20.24 1.34 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-09 32 nd 3.4764 -26.65992 297.6 11.857 35.149 25.05 1.63 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-10 34 nd 0.89227 -25.43576 11 27.249 36.066 0.00 0.10 0.26 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-10 34 nd 0.89227 -25.43576 20.1 27.244 36.069 0.00 0.10 0.23 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-10 34 nd 0.89227 -25.43576 69.1 26.643 36.168 0.03 0.12 0.19 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-10 34 nd 0.89227 -25.43576 77.5 26.54 36.162 0.07 0.13 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-10 34 nd 0.89227 -25.43576 81.4 26.494 36.158 0.19 0.15 0.11 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-10 34 nd 0.89227 -25.43576 94.4 24.377 35.993 4.77 0.31 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-10 34 nd 0.89227 -25.43576 128.4 14.892 35.508 18.95 1.25 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-10 34 nd 0.89227 -25.43576 199.8 12.676 35.234 21.76 1.47 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-10 34 nd 0.89227 -25.43576 299 10.678 34.994 26.25 1.79 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-10 35 nd -2.88793 -24.99891 10.2 26.883 36.267 0.00 0.18 0.25 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-10 35 nd -2.88793 -24.99891 19.2 26.887 36.267 0.00 0.19 0.23 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-10 35 nd -2.88793 -24.99891 34.1 26.893 36.267 0.00 0.20 0.20 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-10 35 nd -2.88793 -24.99891 78.7 20.601 35.938 10.35 0.81 0.17 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-10 35 nd -2.88793 -24.99891 83.3 18.427 35.78 15.57 1.13 0.14 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-10 35 nd -2.88793 -24.99891 87.2 17.437 35.707 20.65 1.44 0.12 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-10 35 nd -2.88793 -24.99891 119.5 14.092 35.42 22.18 1.57 0.10 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-10 35 nd -2.88793 -24.99891 201.3 12.972 35.273 23.95 1.70 0.08 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-10 35 nd -2.88793 -24.99891 300.1 11.413 35.081 29.41 2.02 0.05 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-12 37 nd -8.27609 -24.99577 2.4 25.694 36.279 0.01 0.11 0.30 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-12 37 nd -8.27609 -24.99577 14.3 25.601 36.277 0.01 0.12 0.30 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-12 37 nd -8.27609 -24.99577 25.7 25.594 36.278 0.01 0.12 0.20 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-12 37 nd -8.27609 -24.99577 45.5 25.588 36.278 0.01 0.12 0.20 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-12 37 nd -8.27609 -24.99577 60.9 25.546 36.275 0.01 0.12 0.18 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-12 37 nd -8.27609 -24.99577 70.6 25.519 36.272 0.01 0.12 0.16 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-12 37 nd -8.27609 -24.99577 85.6 25.292 36.272 0.01 0.13 0.15 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-12 37 nd -8.27609 -24.99577 92.3 25.126 36.59 0.01 0.12 0.14 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-12 37 nd -8.27609 -24.99577 98.8 24.931 36.66 0.04 0.11 0.11 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-12 37 nd -8.27609 -24.99577 103.6 24.742 36.707 0.17 0.13 0.11 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-12 37 nd -8.27609 -24.99577 110.2 23.654 36.619 2.19 0.29 0.08 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-12 37 nd -8.27609 -24.99577 120.3 22.182 36.558 3.66 0.44 0.05 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-12 37 nd -8.27609 -24.99577 129.6 20.723 36.377 5.56 0.57 0.04 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-12 37 nd -8.27609 -24.99577 156.9 17.421 35.927 14.10 1.02 0.04 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-12 37 nd -8.27609 -24.99577 199.6 13.238 35.332 23.53 1.59 0.03 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-12 37 nd -8.27609 -24.99577 300.1 8.963 34.801 31.27 2.09 0.03 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-13 38 nd -11.00024 -24.99922 17.9 25.62 36.667 0.01 0.21 0.28 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-13 38 nd -11.00024 -24.99922 31.5 25.618 36.669 0.01 0.20 0.26 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-13 38 nd -11.00024 -24.99922 57.7 24.42 36.908 0.00 0.19 0.24 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-13 38 nd -11.00024 -24.99922 110.3 23.333 37.051 0.00 0.24 0.19 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-13 38 nd -11.00024 -24.99922 123.9 22.906 36.947 0.03 0.28 0.21 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-13 38 nd -11.00024 -24.99922 128.4 22.33 36.81 0.12 0.31 0.16 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-13 38 nd -11.00024 -24.99922 136.5 21.594 36.653 0.54 0.38 0.14 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-13 38 nd -11.00024 -24.99922 140.9 21.06 36.555 1.09 0.44 0.12 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-13 38 nd -11.00024 -24.99922 150.2 19.365 36.233 3.65 0.61 0.10 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-13 38 nd -11.00024 -24.99922 195.6 14.523 35.459 13.55 1.21 0.08 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-13 38 nd -11.00024 -24.99922 300.4 10.25 34.948 28.64 2.19 0.05 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-14 40 nd -14.38067 -24.99658 1.9 25.301 36.836 0.00 0.20 0.31 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-14 40 nd -14.38067 -24.99658 19 25.297 36.847 0.00 0.20 0.28 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-14 40 nd -14.38067 -24.99658 35.2 25.135 36.87 0.00 0.19 0.28 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-14 40 nd -14.38067 -24.99658 63.9 24.808 37.165 0.00 0.19 0.27 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-14 40 nd -14.38067 -24.99658 99.8 23.935 37.192 0.00 0.21 0.20 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-14 40 nd -14.38067 -24.99658 139.1 23.114 37.05 0.01 0.24 0.18 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-14 40 nd -14.38067 -24.99658 146.6 22.962 37.011 0.05 0.26 0.16 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-14 40 nd -14.38067 -24.99658 149.7 22.82 36.977 0.22 0.27 0.10 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-14 40 nd -14.38067 -24.99658 159.5 21.936 36.768 1.15 0.36 0.08 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-14 40 nd -14.38067 -24.99658 221 15.003 35.502 9.98 0.89 0.06 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-14 40 nd -14.38067 -24.99658 300.8 11.758 35.057 19.41 1.47 0.04 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-15 42 nd -18.55974 -24.99919 2.1 24.605 36.972 0.00 0.29 0.28 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-15 42 nd -18.55974 -24.99919 21.7 24.496 36.965 0.00 0.28 0.26 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-15 42 nd -18.55974 -24.99919 39.5 23.519 36.896 0.00 0.27 0.24 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-15 42 nd -18.55974 -24.99919 71.7 22.924 36.903 0.00 0.26 0.19 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-15 42 nd -18.55974 -24.99919 139 22.174 36.842 0.00 0.26 0.18 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-15 42 nd -18.55974 -24.99919 155.2 22.14 36.848 0.00 0.26 0.15 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-15 42 nd -18.55974 -24.99919 165.9 22.113 36.842 0.02 0.27 0.12 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-15 42 nd -18.55974 -24.99919 174.5 22.003 36.814 0.05 0.26 0.09 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-15 42 nd -18.55974 -24.99919 179.1 21.98 36.807 0.06 0.26 0.10 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-15 42 nd -18.55974 -24.99919 300.6 13.159 35.22 14.02 1.08 0.07 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-16 44 nd -21.12928 -22.43899 1.8 24.137 36.937 0.00 0.28 0.27 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-16 44 nd -21.12928 -22.43899 18 24.106 36.933 0.00 0.28 0.24 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-16 44 nd -21.12928 -22.43899 33.1 23.416 36.851 0.00 0.26 0.20 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-16 44 nd -21.12928 -22.43899 60.1 22.482 36.85 0.01 0.25 0.18 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-16 44 nd -21.12928 -22.43899 115.1 21.861 36.789 0.00 0.26 0.13 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-16 44 nd -21.12928 -22.43899 127.9 21.527 36.709 0.01 0.26 0.11 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-16 44 nd -21.12928 -22.43899 138.7 20.838 36.554 0.05 0.25 0.10 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-16 44 nd -21.12928 -22.43899 144.7 20.47 36.472 0.21 0.27 0.08 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-16 44 nd -21.12928 -22.43899 152.4 19.208 36.218 0.75 0.32 0.03 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-16 44 nd -21.12928 -22.43899 209 15.991 35.608 5.21 0.56 0.03 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-16 44 nd -21.12928 -22.43899 300.3 13.163 35.198 12.03 0.97 0.03 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-16 46 nd -21.10335 -22.37868 41.2 23.269 36.862 0.03 0.16 0.20 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-16 46 nd -21.10335 -22.37868 75.2 22.462 36.825 0.03 0.15 0.19 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-16 46 nd -21.10335 -22.37868 129.8 21.876 36.783 0.03 0.15 0.18 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-16 46 nd -21.10335 -22.37868 159.7 21.577 36.725 1.41 0.28 0.15 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-16 46 nd -21.10335 -22.37868 170 21.08 36.605 2.42 0.34 0.13 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-16 46 nd -21.10335 -22.37868 173.7 20.511 36.488 2.48 0.36 0.08 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-16 46 nd -21.10335 -22.37868 179.1 19.811 36.351 2.68 0.37 0.06 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-16 46 nd -21.10335 -22.37868 200.7 18.169 36.004 4.16 0.44 0.10 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-16 46 nd -21.10335 -22.37868 272.1 14.728 35.42 9.56 0.72 0.07 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-17 47 nd -22.14294 -20.19863 1.4 23.742 36.839 0.00 0.25 0.28 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-17 47 nd -22.14294 -20.19863 19.9 23.744 36.838 0.00 0.26 0.25 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-17 47 nd -22.14294 -20.19863 35.6 23.267 36.778 0.00 0.27 0.20 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-17 47 nd -22.14294 -20.19863 64.5 21.819 36.701 0.00 0.26 0.16 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-17 47 nd -22.14294 -20.19863 128.7 21.3 36.681 0.00 0.23 0.10 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-17 47 nd -22.14294 -20.19863 139.1 21.223 36.664 0.00 0.22 0.08 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-17 47 nd -22.14294 -20.19863 164.6 20.902 36.577 0.09 0.23 0.05 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-17 47 nd -22.14294 -20.19863 179.2 18.829 36.096 0.81 0.31 0.04 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-17 47 nd -22.14294 -20.19863 225 16.206 35.634 4.95 0.54 0.03 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-17 47 nd -22.14294 -20.19863 299.9 13.73 35.281 11.41 0.93 0.03 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-18 49 nd -23.76301 -16.52736 1.5 22.98 36.54 0.00 0.29 0.29 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-18 49 nd -23.76301 -16.52736 39.1 21.848 36.47 0.00 0.29 0.24 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-18 49 nd -23.76301 -16.52736 70.6 20.536 36.442 0.00 0.27 0.19 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-18 49 nd -23.76301 -16.52736 149.9 20.137 36.411 0.00 0.26 0.12 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-18 49 nd -23.76301 -16.52736 159.9 20.054 36.389 0.01 0.26 0.10 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-18 49 nd -23.76301 -16.52736 163.6 20.044 36.386 0.01 0.25 0.04 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-18 49 nd -23.76301 -16.52736 170.1 19.969 36.367 0.02 0.25 0.05 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-18 49 nd -23.76301 -16.52736 175 19.925 36.356 0.04 0.24 0.04 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-18 49 nd -23.76301 -16.52736 245.9 17.037 35.735 3.02 0.43 0.04 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-18 49 nd -23.76301 -16.52736 300.4 14.507 35.363 7.96 0.71 0.03 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-19 50 nd -26.14092 -11.05722 18.5 20.742 36.088 0.00 0.26 0.21 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-19 50 nd -26.14092 -11.05722 31.4 19.621 36.03 0.00 0.27 0.24 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-19 50 nd -26.14092 -11.05722 56.3 18.63 35.961 0.00 0.26 0.23 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-19 50 nd -26.14092 -11.05722 81.1 18.213 35.929 0.00 0.26 0.21 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-19 50 nd -26.14092 -11.05722 101.1 18.076 35.948 0.01 0.25 0.20 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-19 50 nd -26.14092 -11.05722 116.2 17.915 35.921 0.01 0.25 0.18 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-19 50 nd -26.14092 -11.05722 128.2 17.775 35.895 0.17 0.25 0.18 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-19 50 nd -26.14092 -11.05722 135.2 17.676 35.874 0.45 0.26 0.14 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-19 50 nd -26.14092 -11.05722 150.8 17.529 35.842 0.91 0.28 0.12 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-19 50 nd -26.14092 -11.05722 170.7 17.337 35.797 1.69 0.32 0.09 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-19 50 nd -26.14092 -11.05722 191 15.97 35.53 4.28 0.48 0.07 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-19 50 nd -26.14092 -11.05722 201.5 15.434 35.444 5.52 0.57 0.06 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-19 50 nd -26.14092 -11.05722 299.4 13.133 35.187 10.29 0.85 0.04 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-20 51 nd -27.39677 -8.11673 2 21.274 36.044 0.00 0.28 0.24 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-20 51 nd -27.39677 -8.11673 13.1 21.24 36.041 0.00 0.29 0.21 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-20 51 nd -27.39677 -8.11673 23.4 20.021 36.013 0.00 0.29 0.19 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-20 51 nd -27.39677 -8.11673 43.3 19.653 36.025 0.00 0.30 0.17 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-20 51 nd -27.39677 -8.11673 85 17.527 35.715 0.01 0.29 0.14 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-20 51 nd -27.39677 -8.11673 93.9 17.359 35.704 0.32 0.32 0.14 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-20 51 nd -27.39677 -8.11673 97.7 17.067 35.654 1.33 0.39 0.15 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-20 51 nd -27.39677 -8.11673 103.2 16.715 35.601 2.24 0.44 0.12 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-20 51 nd -27.39677 -8.11673 112.7 16.319 35.534 3.85 0.53 0.10 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-20 51 nd -27.39677 -8.11673 147.5 15.157 35.359 7.43 0.72 0.10 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-20 51 nd -27.39677 -8.11673 200.3 13.853 35.212 9.90 0.86 0.08 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-20 51 nd -27.39677 -8.11673 300.8 12.115 35.053 13.17 1.05 0.05 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-21 53 nd -28.85446 -4.68811 1.3 21.472 36.144 0.00 0.25 0.25 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-21 53 nd -28.85446 -4.68811 17 20.799 36.121 0.00 0.24 0.24 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-21 53 nd -28.85446 -4.68811 31.1 20.277 36.082 0.00 0.23 0.20 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-21 53 nd -28.85446 -4.68811 56.1 19.797 36.059 0.00 0.23 0.18 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-21 53 nd -28.85446 -4.68811 109.6 18.059 35.788 0.00 0.24 0.10 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-21 53 nd -28.85446 -4.68811 121.4 17.352 35.694 0.15 0.24 0.14 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-21 53 nd -28.85446 -4.68811 128 16.922 35.625 1.23 0.31 0.09 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-21 53 nd -28.85446 -4.68811 133.6 16.755 35.611 2.37 0.38 0.10 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-21 53 nd -28.85446 -4.68811 149.5 16.304 35.543 3.82 0.47 0.10 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-21 53 nd -28.85446 -4.68811 190.8 14.684 35.296 8.45 0.73 0.09 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-21 53 nd -28.85446 -4.68811 299.4 12.449 35.076 13.79 1.05 0.07 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-22 55 nd -30.67318 -0.2998 8.1 18.6 35.708 0.00 0.22 0.26 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-22 55 nd -30.67318 -0.2998 15.4 17.992 35.676 0.00 0.21 0.27 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-22 55 nd -30.67318 -0.2998 28.4 17.573 35.646 0.00 0.20 0.25 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-22 55 nd -30.67318 -0.2998 46.8 17.084 35.631 0.04 0.21 0.21 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-22 55 nd -30.67318 -0.2998 55.4 16.981 35.622 0.13 0.22 0.20 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-22 55 nd -30.67318 -0.2998 64 16.856 35.607 0.55 0.25 0.19 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-22 55 nd -30.67318 -0.2998 70.3 16.824 35.606 0.86 0.26 0.16 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-22 55 nd -30.67318 -0.2998 74.9 16.775 35.604 1.39 0.27 0.13 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-22 55 nd -30.67318 -0.2998 96.1 16.555 35.587 1.76 0.29 0.11 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-22 55 nd -30.67318 -0.2998 199.7 15.415 35.429 2.61 0.36 0.09 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-22 55 nd -30.67318 -0.2998 299.5 13.917 35.221 7.16 0.63 0.05 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-23 57 nd -32.52798 4.23609 1.8 17.605 35.532 0.00 0.29 0.29 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-23 57 nd -32.52798 4.23609 8.1 17.618 35.534 0.00 0.29 0.27 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-23 57 nd -32.52798 4.23609 15 17.149 35.502 0.00 0.29 0.24 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-23 57 nd -32.52798 4.23609 55.3 16.414 35.502 0.05 0.30 0.18 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-23 57 nd -32.52798 4.23609 58.3 16.247 35.467 0.38 0.33 0.17 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-23 57 nd -32.52798 4.23609 69.5 16.187 35.489 1.14 0.38 0.13 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-23 57 nd -32.52798 4.23609 75 16.078 35.47 0.77 0.36 0.11 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-23 57 nd -32.52798 4.23609 86.1 15.995 35.477 0.18 0.34 0.10 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-23 57 nd -32.52798 4.23609 298.2 13.346 35.179 8.53 0.80 0.06 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-24 59 nd -33.64581 8.91522 6.4 17.988 35.549 0.01 0.21 0.24 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-24 59 nd -33.64581 8.91522 10 17.52 35.547 0.00 0.22 0.20 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-24 59 nd -33.64581 8.91522 17.7 17.328 35.537 0.00 0.21 0.12 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-24 59 nd -33.64581 8.91522 29.7 16.559 35.507 0.00 0.21 0.12 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-24 59 nd -33.64581 8.91522 35.3 16.328 35.517 0.24 0.23 0.14 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-24 59 nd -33.64581 8.91522 41.6 16.185 35.524 0.88 0.27 0.12 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-24 59 nd -33.64581 8.91522 49.3 16.17 35.525 0.99 0.28 0.12 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-24 59 nd -33.64581 8.91522 63.4 16.115 35.524 1.02 0.28 0.01 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-24 59 nd -33.64581 8.91522 100.1 15.815 35.498 2.20 0.32 0.09 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-24 59 nd -33.64581 8.91522 198.7 14.381 35.259 4.02 0.44 0.09 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-24 59 nd -33.64581 8.91522 303.8 13.121 35.131 8.29 0.67 0.07 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-24 61 nd -33.90676 10.30315 1.7 18.358 35.532 0.03 0.08 0.19 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-24 61 nd -33.90676 10.30315 4.9 18.381 35.53 0.03 0.08 0.18 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-24 61 nd -33.90676 10.30315 9.5 17.581 35.517 0.04 0.09 0.19 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-24 61 nd -33.90676 10.30315 14.9 17.214 35.516 0.46 0.13 0.13 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-24 61 nd -33.90676 10.30315 19.9 16.911 35.51 1.38 0.19 0.16 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-24 61 nd -33.90676 10.30315 24.7 16.188 35.509 1.60 0.22 0.09 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-24 61 nd -33.90676 10.30315 26.6 16.088 35.512 1.81 0.25 0.16 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-24 61 nd -33.90676 10.30315 30.7 16.045 35.515 2.01 0.27 0.14 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-24 61 nd -33.90676 10.30315 39.9 15.99 35.517 2.37 0.30 0.12 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-24 61 nd -33.90676 10.30315 60.4 15.934 35.514 2.86 0.33 0.12 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-24 61 nd -33.90676 10.30315 99.4 15.852 35.506 4.30 0.40 0.10 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd AMT17 2005-11-24 61 nd -33.90676 10.30315 199 15.455 35.472 5.54 0.48 0.09 2 South Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-08 17 24 26.5075 -76.6375 11 nd nd 0.00 0.00 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-08 17 23 26.5075 -76.6375 11 nd nd 0.00 0.00 0.22 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-08 17 22 26.5075 -76.6375 15 nd nd 0.23 0.01 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-08 17 21 26.5075 -76.6375 55 nd nd 0.10 0.00 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-08 17 19 26.5075 -76.6375 201 nd nd 0.93 0.04 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-08 17 17 26.5075 -76.6375 388 nd nd 5.32 0.25 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-08 17 15 26.5075 -76.6375 624 nd nd 15.15 0.98 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-08 17 11 26.5075 -76.6375 1316 nd nd 18.46 1.26 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-08 17 1 26.5075 -76.6375 4687 nd nd 20.28 1.44 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-10 23 24 26.5024 -75.9103 17 nd nd 0.00 0.00 0.11 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-10 23 23 26.5024 -75.9103 57 nd nd 0.00 0.00 0.11 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-10 23 22 26.5024 -75.9103 108 nd nd 0.00 0.00 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-10 23 21 26.5024 -75.9103 208 nd nd 0.99 0.01 0.11 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-10 23 20 26.5024 -75.9103 309 nd nd 2.80 0.09 0.14 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-10 23 18 26.5024 -75.9103 510 nd nd 7.90 0.40 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-10 23 11 26.5024 -75.9103 2029 nd nd 19.50 1.17 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-10 23 9 26.5024 -75.9103 2639 nd nd 19.20 1.24 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-10 23 1 26.5024 -75.9103 4819 nd nd 23.10 1.42 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-10 24 23 26.4917 -75.7036 17 nd nd 0.00 0.00 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-10 24 24 26.4917 -75.7036 17 nd nd 0.00 0.00 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-11 27 24 26.5155 -75.0746 18 nd nd 0.00 0.00 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-11 27 23 26.5155 -75.0746 58 nd nd 0.00 0.00 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-11 27 22 26.5155 -75.0746 108 nd nd 0.40 0.07 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-11 27 21 26.5155 -75.0746 208 nd nd 1.70 0.04 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-11 27 20 26.5155 -75.0746 309 nd nd 2.90 0.12 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-11 27 19 26.5155 -75.0746 409 nd nd 5.30 0.24 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-11 27 14 26.5155 -75.0746 1116 nd nd 21.80 1.41 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-11 27 7 26.5155 -75.0746 3246 nd nd 18.60 1.22 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-11 27 4 26.5155 -75.0746 4167 nd nd 20.20 1.28 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-12 32 24 26.5012 -73.9299 17 nd nd 0.10 0.04 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-12 32 23 26.5012 -73.9299 57 nd nd 0.10 0.04 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-12 32 22 26.5012 -73.9299 108 nd nd 0.10 0.04 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-12 32 21 26.5012 -73.9299 208 nd nd 1.00 0.07 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-12 32 20 26.5012 -73.9299 309 nd nd 2.90 0.14 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-12 32 18 26.5012 -73.9299 510 nd nd 8.50 0.51 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-12 32 14 26.5012 -73.9299 1116 nd nd 21.20 1.50 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-12 32 5 26.5012 -73.9299 3743 nd nd 18.20 1.24 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-13 36 24 26.4996 -72.486 19 nd nd 0.08 0.03 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-13 36 23 26.4996 -72.486 59 nd nd 0.11 0.02 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-13 36 22 26.4996 -72.486 110 nd nd 0.07 0.03 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-13 36 21 26.4996 -72.486 210 nd nd 0.70 0.05 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-13 36 20 26.4996 -72.486 361 nd nd 3.70 0.17 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-13 36 18 26.4996 -72.486 714 nd nd 14.60 0.97 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-13 36 14 26.4996 -72.486 1573 nd nd 18.40 1.23 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-13 36 10 26.4996 -72.486 2791 nd nd 19.00 1.25 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-13 36 5 26.4996 -72.486 4327 nd nd 18.30 1.41 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-13 36 1 26.4996 -72.486 5290 nd nd 22.50 1.62 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-14 40 24 26.49 -70.9867 20 nd nd 0.10 0.05 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-14 40 23 26.49 -70.9867 59 nd nd 0.10 0.02 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-14 40 22 26.49 -70.9867 110 nd nd 0.37 0.02 0.17 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-14 40 21 26.49 -70.9867 211 nd nd 2.20 0.08 0.13 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-14 40 20 26.49 -70.9867 362 nd nd 4.70 0.23 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-14 40 19 26.49 -70.9867 512 nd nd 7.80 0.45 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-14 40 10 26.49 -70.9867 2757 nd nd 18.60 1.37 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-15 44 23 25.0008 -69.5062 59 nd nd 0.10 0.06 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-15 44 22 25.0008 -69.5062 110 nd nd 0.20 0.04 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-15 44 21 25.0008 -69.5062 210 nd nd 2.30 0.11 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-15 44 19 25.0008 -69.5062 511 nd nd 9.59 0.60 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-15 44 14 25.0008 -69.5062 1601 nd nd 17.01 1.33 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-15 44 10 25.0008 -69.5062 2784 nd nd 19.21 1.33 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-15 44 7 25.0008 -69.5062 3708 nd nd 19.21 1.35 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-15 44 1 25.0008 -69.5062 5703 nd nd 23.20 1.63 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-17 50 24 24.4958 -65.4635 19 nd nd 0.10 0.00 0.14 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-17 50 23 24.4958 -65.4635 60 nd nd 0.30 0.01 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-17 50 22 24.4958 -65.4635 110 nd nd 0.20 0.01 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-17 50 21 24.4958 -65.4635 210 nd nd 2.91 0.10 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-17 50 20 24.4958 -65.4635 361 nd nd 6.22 0.28 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-17 50 19 24.4958 -65.4635 512 nd nd 9.00 0.58 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-17 50 18 24.4958 -65.4635 714 nd nd 19.90 1.33 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-17 50 16 24.4958 -65.4635 1118 nd nd 22.30 1.41 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-17 50 1 24.4958 -65.4635 5662 nd nd 22.30 1.61 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-19 56 24 24.5012 -61.063 21 nd nd 0.10 0.00 0.13 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-19 56 23 24.5012 -61.063 62 nd nd 0.00 0.00 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-19 56 22 24.5012 -61.063 163 nd nd 0.80 0.01 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-19 56 20 24.5012 -61.063 363 nd nd 6.00 0.32 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-19 56 19 24.5012 -61.063 513 nd nd 12.00 0.66 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-19 56 18 24.5012 -61.063 714 nd nd 22.20 1.32 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-19 56 10 24.5012 -61.063 2846 nd nd 21.20 1.37 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-19 56 5 24.5012 -61.063 4639 nd nd 21.00 1.32 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-21 62 24 24.5 -56.6665 22 nd nd 0.00 0.00 0.20 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-21 62 23 24.5 -56.6665 63 nd nd 0.10 0.00 0.22 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-21 62 22 24.5 -56.6665 113 nd nd 0.10 0.01 0.18 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-21 62 21 24.5 -56.6665 213 nd nd 2.40 0.08 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-21 62 20 24.5 -56.6665 364 nd nd 6.01 0.30 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-21 62 19 24.5 -56.6665 515 nd nd 12.55 0.71 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-21 62 14 24.5 -56.6665 1628 nd nd 19.30 1.35 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-21 62 12 24.5 -56.6665 2187 nd nd 20.40 1.35 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-21 62 10 24.5 -56.6665 2848 nd nd 23.87 1.37 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-21 62 1 24.5 -56.6665 6001 nd nd 27.64 1.71 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-22 65 24 24.5013 -54.4653 20 nd nd 0.00 0.00 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-22 65 23 24.5013 -54.4653 60 nd nd 0.00 0.00 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-22 65 22 24.5013 -54.4653 110 nd nd 0.20 0.00 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-22 65 21 24.5013 -54.4653 210 nd nd 2.70 0.09 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-22 65 20 24.5013 -54.4653 360 nd nd 6.40 0.30 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-22 65 19 24.5013 -54.4653 510 nd nd 11.00 0.66 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-22 65 18 24.5013 -54.4653 711 nd nd 20.80 1.31 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-22 65 17 24.5013 -54.4653 913 nd nd 25.30 1.73 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-22 65 15 24.5013 -54.4653 1316 nd nd 20.00 1.34 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-22 65 9 24.5013 -54.4653 2945 nd nd 20.90 1.41 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-22 65 3 24.5013 -54.4653 4785 nd nd 23.10 1.55 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-23 69 24 24.4994 -52.1614 20 nd nd 0.40 0.02 0.21 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-23 69 23 24.4994 -52.1614 60 nd nd 0.00 0.01 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-23 69 22 24.4994 -52.1614 111 nd nd 0.10 0.01 0.21 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-23 69 21 24.4994 -52.1614 211 nd nd 3.80 0.16 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-23 69 15 24.4994 -52.1614 967 nd nd 26.10 1.75 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-23 69 13 24.4994 -52.1614 1422 nd nd 20.40 1.33 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-23 69 11 24.4994 -52.1614 2030 nd nd 20.10 1.31 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-23 69 9 24.4994 -52.1614 2639 nd nd 20.90 1.38 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-23 69 3 24.4994 -52.1614 4481 nd nd 22.27 1.53 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-24 72 24 24.4995 -50.4417 19 nd nd 0.20 0.04 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-24 72 23 24.4995 -50.4417 59 nd nd 0.20 0.03 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-24 72 22 24.4995 -50.4417 110 nd nd 0.20 0.04 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-24 72 21 24.4995 -50.4417 210 nd nd 4.80 0.22 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-24 72 20 24.4995 -50.4417 361 nd nd 9.00 0.45 0.13 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-24 72 18 24.4995 -50.4417 714 nd nd 23.40 1.45 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-24 72 16 24.4995 -50.4417 1119 nd nd 24.20 1.54 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-24 72 14 24.4995 -50.4417 1575 nd nd 21.10 1.34 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-24 72 12 24.4995 -50.4417 2081 nd nd 21.10 1.37 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-24 72 8 24.4995 -50.4417 3099 nd nd 21.40 1.46 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-24 72 4 24.4995 -50.4417 4122 nd nd 22.30 1.47 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-24 72 1 24.4995 -50.4417 4792 nd nd 20.28 1.59 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-25 76 24 24.5055 -47.9626 16 nd nd 0.00 0.00 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-25 76 23 24.5055 -47.9626 56 nd nd 0.00 0.00 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-25 76 22 24.5055 -47.9626 107 nd nd 0.10 0.00 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-25 76 21 24.5055 -47.9626 207 nd nd 2.50 0.11 0.25 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-25 76 20 24.5055 -47.9626 358 nd nd 9.40 0.51 0.20 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-25 76 19 24.5055 -47.9626 509 nd nd 14.40 0.84 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-25 76 18 24.5055 -47.9626 712 nd nd 20.90 1.30 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-25 76 16 24.5055 -47.9626 1014 nd nd 27.20 1.79 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-25 76 12 24.5055 -47.9626 1824 nd nd 20.60 1.35 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-25 76 8 24.5055 -47.9626 2638 nd nd 21.20 1.41 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-25 76 4 24.5055 -47.9626 3453 nd nd 21.90 1.45 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-25 76 1 24.5055 -47.9626 4010 nd nd 22.00 1.51 0.16 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-26 80 24 24.5048 -45.4903 14 nd nd 0.10 0.00 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-26 80 23 24.5048 -45.4903 54 nd nd 0.10 0.01 0.17 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-26 80 22 24.5048 -45.4903 105 nd nd 0.10 0.00 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-26 80 21 24.5048 -45.4903 205 nd nd 1.30 0.03 0.11 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-26 80 20 24.5048 -45.4903 357 nd nd 7.60 0.39 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-26 80 14 24.5048 -45.4903 1519 nd nd 21.90 1.46 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-26 80 12 24.5048 -45.4903 1823 nd nd 20.50 1.37 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-26 80 8 24.5048 -45.4903 2432 nd nd 21.90 1.42 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-26 80 1 24.5048 -45.4903 3466 nd nd 22.70 1.50 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-27 84 24 24.5097 -43.0072 18 nd nd 0.10 0.00 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-27 84 23 24.5097 -43.0072 58 nd nd 0.10 0.01 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-27 84 22 24.5097 -43.0072 108 nd nd 0.10 0.00 0.13 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-27 84 21 24.5097 -43.0072 209 nd nd 3.70 0.18 0.14 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-27 84 20 24.5097 -43.0072 359 nd nd 9.70 0.56 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-27 84 18 24.5097 -43.0072 705 nd nd 24.00 1.52 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-27 84 16 24.5097 -43.0072 1107 nd nd 26.10 1.77 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-27 84 4 24.5097 -43.0072 3532 nd nd 22.80 1.66 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-27 84 1 24.5097 -43.0072 4169 nd nd 23.10 1.58 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-28 86 24 24.5087 -41.6399 19 nd nd 0.10 0.00 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-28 86 23 24.5087 -41.6399 60 nd nd 0.00 0.00 0.16 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-28 86 22 24.5087 -41.6399 110 nd nd 0.00 0.02 0.13 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-28 86 21 24.5087 -41.6399 210 nd nd 3.70 0.16 0.14 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-28 86 20 24.5087 -41.6399 359 nd nd 8.30 0.43 0.13 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-28 86 19 24.5087 -41.6399 508 nd nd 13.70 0.77 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-28 86 16 24.5087 -41.6399 1101 nd nd 26.50 1.74 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-28 86 14 24.5087 -41.6399 1495 nd nd 22.80 1.49 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-28 86 8 24.5087 -41.6399 3024 nd nd 22.20 1.48 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-29 90 24 24.5 -38.5133 19 nd nd 0.10 0.00 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-29 90 23 24.5 -38.5133 60 nd nd 0.10 0.00 0.31 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-29 90 22 24.5 -38.5133 111 nd nd 0.10 0.00 0.36 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-29 90 14 24.5 -38.5133 1523 nd nd 21.80 1.33 0.24 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-29 90 10 24.5 -38.5133 2532 nd nd 21.30 1.31 0.33 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-29 90 5 24.5 -38.5133 3800 nd nd 22.30 1.41 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-30 94 24 24.5045 -35.2287 19 nd nd 0.10 0.00 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-30 94 23 24.5045 -35.2287 59 nd nd 0.10 0.00 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-30 94 20 24.5045 -35.2287 361 nd nd 7.90 0.40 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-30 94 18 24.5045 -35.2287 712 nd nd 21.60 1.30 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-30 94 14 24.5045 -35.2287 1620 nd nd 21.60 1.41 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-01 96 22 24.4991 -33.5732 112 nd nd 0.18 0.00 0.13 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-01 96 21 24.4991 -33.5732 213 nd nd 7.10 0.36 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-01 96 20 24.4991 -33.5732 364 nd nd 12.40 0.70 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-01 96 18 24.4991 -33.5732 717 nd nd 23.70 1.49 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-01 96 16 24.4991 -33.5732 1121 nd nd 26.40 1.75 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-01 96 12 24.4991 -33.5732 2237 nd nd 21.90 1.49 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-01 96 1 24.4991 -33.5732 5992 nd nd 23.50 1.59 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-02 100 24 24.5015 -29.8901 21 nd nd 0.10 0.01 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-02 100 23 24.5015 -29.8901 61 nd nd 0.10 0.01 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-02 100 20 24.5015 -29.8901 362 nd nd 10.50 0.59 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-02 100 10 24.5015 -29.8901 2846 nd nd 21.90 1.45 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-02 100 5 24.5015 -29.8901 4633 nd nd 23.50 1.58 0.15 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-03 102 24 24.5013 -28.0686 19 nd nd 0.10 0.01 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-03 102 23 24.5013 -28.0686 59 nd nd 0.10 0.01 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-03 102 22 24.5013 -28.0686 110 nd nd 2.50 0.14 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-03 102 20 24.5013 -28.0686 362 nd nd 13.80 0.76 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-03 102 10 24.5013 -28.0686 2794 nd nd 22.40 1.48 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-03 102 1 24.5013 -28.0686 5698 nd nd 23.80 1.55 0.22 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-04 104 24 24.499 -26.2312 18 nd nd 0.10 0.02 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-04 104 23 24.499 -26.2312 58 nd nd 0.10 0.02 0.18 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-04 104 22 24.499 -26.2312 109 nd nd 0.80 0.05 0.12 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-04 104 21 24.499 -26.2312 209 nd nd 4.30 0.21 0.13 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-04 104 18 24.499 -26.2312 713 nd nd 27.70 1.79 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-05 108 20 24.7382 -22.8223 310 nd nd 17.30 1.02 0.26 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-05 108 17 24.7382 -22.8223 663 nd nd 25.00 1.53 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-05 108 1 24.7382 -22.8223 4974 nd nd 23.70 1.57 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-06 112 20 25.6499 -20.2425 107 nd nd 5.50 0.29 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-06 112 18 25.6499 -20.2425 307 nd nd 10.10 0.52 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-07 114 17 26.1336 -18.9098 104 nd nd 3.90 0.26 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-07 114 16 26.1336 -18.9098 204 nd nd 9.60 0.55 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-08 118 20 27.0432 -16.122 12 nd nd 0.10 0.02 0.26 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-08 118 18 27.0432 -16.122 52 nd nd 0.20 0.05 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-08 118 17 27.0432 -16.122 103 nd nd 4.00 0.25 0.18 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-14 39 carboys 26.5081 -71.3433 0 nd nd 0.04 0.03 0.17 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-17 49 carboys 24.5029 -66.1923 0 nd nd 0.00 0.01 0.14 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-20 58 carboys 24.5154 -59.5918 0 nd nd 0.00 0.01 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-26 78 carboys 24.4958 -46.5747 0 nd nd 0.00 0.01 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-04-29 89 carboys 24.4978 -39.2451 0 nd nd 0.00 0.00 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-02 98 carboys 24.4995 -31.7308 0 nd nd 0.00 0.00 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-05 107 carboys 24.5134 -23.4947 0 nd nd 0.10 0.02 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd D279 2004-05-08 117 carboys 26.8145 -16.7846 0 nd nd 0.00 0.02 0.17 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-03 3 nd 36.2308 -69.1407 1007.9 7.302 35.1149 19.46 1.28 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-04 6 nd 36.6401 -70.2625 16 21.855 36.3275 0.00 0.00 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-04 6 nd 36.6401 -70.2625 55.7 21.863 36.3289 0.00 0.00 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-04 6 nd 36.6401 -70.2625 105.2 21.096 36.3733 1.76 0.11 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-05 7 nd 36.7385 -70.5589 12.3 15.475 35.0237 0.00 0.17 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-05 7 nd 36.7385 -70.5589 43.9 14.13 35.1429 0.55 0.24 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-05 8 nd 36.8665 -70.8689 48.6 11.876 34.7372 3.61 0.38 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-06 11 nd 37.3226 -71.6791 44.5 12.743 34.7013 1.79 0.25 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-06 12 nd 37.4429 -71.9513 41.3 16.334 35.3914 0.00 0.06 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-06 13 nd 37.611 -72.2016 3011 2.275 34.8997 15.70 1.11 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-08 14 nd 36.0148 -74.8129 10.9 10.379 33.5686 0.57 0.25 0.11 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-08 14 nd 36.0148 -74.8129 51.1 9.366 33.545 1.47 0.36 0.14 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-08 14 nd 36.0148 -74.8129 101.2 9.064 33.5264 1.86 0.43 0.13 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-08 14 nd 36.0148 -74.8129 115.4 9.092 33.5564 1.92 0.43 0.11 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-08 14 nd 36.0148 -74.8129 11.5 11.863 34.0038 0.00 0.17 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-08 15 nd 35.9944 -74.7959 51.4 11.922 34.1203 0.18 0.20 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-08 15 nd 35.9944 -74.7959 150.9 10.312 34.4137 2.70 0.44 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-08 16 nd 35.9771 -74.7738 11.7 10.457 33.6804 0.79 0.29 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-08 17 nd 35.9521 -74.7374 51.9 10.445 33.7657 1.02 0.32 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-08 17 nd 35.9521 -74.7374 100.2 8.09 33.5552 1.89 0.46 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-09 20 nd 35.6493 -74.2791 1005 4.202 34.9621 18.54 1.20 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-09 20 nd 35.6493 -74.2791 1506 3.733 34.9431 17.99 1.18 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-09 20 nd 35.6493 -74.2791 2504.3 3.01 34.9346 18.02 1.20 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-09 20 nd 35.6493 -74.2791 12.2 24.799 36.3796 0.14 0.01 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-09 23 nd 35.597 -74.117 13.3 24.634 36.3728 0.31 0.00 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-09 23 nd 35.597 -74.117 53.4 24.638 36.3723 0.92 0.01 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-10 24 nd 35.3618 -73.7694 152.9 21.955 36.8356 1.48 0.04 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-10 24 nd 35.3618 -73.7694 203.2 20.499 36.7781 1.59 0.06 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-10 24 nd 35.3618 -73.7694 503 16.371 36.2397 11.30 0.58 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-10 24 nd 35.3618 -73.7694 13.1 21.66 36.6121 0.09 0.02 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-10 24 nd 35.3618 -73.7694 42.6 20.901 36.6558 0.17 0.03 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-10 24 nd 35.3618 -73.7694 103 20.552 36.6662 0.46 0.03 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-10 25 nd 35.1587 -73.4702 202.9 19.209 36.6796 2.05 0.09 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-10 26 nd 35.2951 -72.9348 13.7 20.839 36.5626 0.02 0.01 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-10 27 nd 35.4184 -72.4071 304.7 18.697 36.6603 1.81 0.07 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-11 28 nd 35.5656 -71.8587 13 21.476 36.4436 0.11 0.01 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-11 28 nd 35.5656 -71.8587 52.9 21.485 36.4457 0.13 0.00 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-11 29 nd 35.6994 -71.3292 303.3 18.714 36.6511 2.48 0.11 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-11 29 nd 35.6994 -71.3292 13.6 20.887 36.5682 0.05 0.00 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-11 29 nd 35.6994 -71.3292 53.5 20.795 36.5679 0.06 0.00 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-11 29 nd 35.6994 -71.3292 103.6 19.96 36.7103 1.49 0.05 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-11 30 nd 35.8329 -70.7996 203.7 18.963 36.6593 2.43 0.09 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-11 30 nd 35.8329 -70.7996 303.8 18.649 36.6415 2.62 0.10 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-11 30 nd 35.8329 -70.7996 403.8 18.258 36.5839 3.72 0.17 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-11 31 nd 35.9674 -70.247 53.8 19.26 36.6771 0.33 0.00 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-11 31 nd 35.9674 -70.247 103.9 19.213 36.6823 0.71 0.01 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-12 32 nd 36.1131 -69.6938 203.8 18.698 36.6397 2.56 0.11 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-12 32 nd 36.1131 -69.6938 304.7 18.32 36.5755 3.86 0.17 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-12 32 nd 36.1131 -69.6938 404.8 18.046 36.5497 4.30 0.20 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-12 32 nd 36.1131 -69.6938 505 17.109 36.3719 7.45 0.39 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-12 32 nd 36.1131 -69.6938 13.3 21.582 36.5238 0.02 0.00 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-12 32 nd 36.1131 -69.6938 45.2 19.501 36.6574 0.07 0.00 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-12 32 nd 36.1131 -69.6938 103.4 19.015 36.6605 1.19 0.03 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-12 33 nd 36.2562 -69.1291 203.6 18.529 36.6527 2.35 0.08 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-14 38 nd 36.2469 -66.0857 13.8 20.885 36.5227 0.04 0.01 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-14 38 nd 36.2469 -66.0857 49.6 20.845 36.5309 0.11 0.01 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-14 39 nd 36.2348 -65.4562 203.2 19.147 36.6451 3.60 0.16 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-14 39 nd 36.2348 -65.4562 302.6 18.741 36.6534 2.58 0.11 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-14 39 nd 36.2348 -65.4562 403.2 18.396 36.6192 3.06 0.14 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-14 39 nd 36.2348 -65.4562 2006.4 3.661 34.9535 18.31 1.19 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-15 41 nd 36.2643 -64.2296 14.2 20.916 36.4779 0.06 0.01 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-15 41 nd 36.2643 -64.2296 47.1 20.599 36.4796 0.32 0.01 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-15 41 nd 36.2643 -64.2296 104.1 19.597 36.679 2.32 0.09 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-15 42 nd 36.2457 -63.6253 204.2 18.543 36.646 2.48 0.10 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-16 44 nd 36.2616 -62.4064 14.1 19.938 36.6515 0.08 0.01 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-16 44 nd 36.2616 -62.4064 53.8 18.876 36.6275 0.15 0.01 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-16 44 nd 36.2616 -62.4064 84.3 18.595 36.6203 1.51 0.06 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-16 45 nd 36.2586 -61.7725 203.9 18.268 36.6102 2.67 0.11 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-16 45 nd 36.2586 -61.7725 303.9 18.16 36.5954 2.91 0.15 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-16 45 nd 36.2586 -61.7725 403.2 17.99 36.5629 3.48 0.16 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-16 45 nd 36.2586 -61.7725 1994.3 3.713 34.956 18.39 1.19 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-16 46 nd 36.2424 -61.1642 14.1 19.807 36.6652 0.02 0.00 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-16 46 nd 36.2424 -61.1642 54 19.583 36.6597 0.06 0.00 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-16 46 nd 36.2424 -61.1642 103.1 18.634 36.6323 1.77 0.05 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-17 47 nd 36.2468 -60.5295 204 18.305 36.6055 2.57 0.10 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-17 47 nd 36.2468 -60.5295 303.2 18.14 36.5828 3.17 0.12 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-17 47 nd 36.2468 -60.5295 402.9 17.699 36.4844 5.32 0.25 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-18 51 nd 36.0976 -58.7126 13.6 19.306 36.6669 0.02 0.00 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-18 51 nd 36.0976 -58.7126 28.6 19.229 36.667 0.04 0.00 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-18 51 nd 36.0976 -58.7126 103.6 18.898 36.6547 1.75 0.06 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-18 52 nd 36.0105 -58.0828 203.5 18.5 36.6282 2.37 0.10 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-18 52 nd 36.0105 -58.0828 303.5 18.361 36.6227 2.56 0.12 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-18 52 nd 36.0105 -58.0828 403.8 18.239 36.6034 2.98 0.13 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-18 53 nd 36.1682 -57.2539 14.9 19.034 36.6551 0.03 0.00 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-18 53 nd 36.1682 -57.2539 44.9 18.917 36.6556 0.43 0.00 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-18 53 nd 36.1682 -57.2539 105 18.641 36.654 2.26 0.08 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-19 54 nd 36.235 -56.4376 205.1 18.332 36.6111 2.62 0.10 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-19 54 nd 36.235 -56.4376 303.6 18.217 36.5965 2.93 0.13 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-19 55 nd 36.2441 -55.6084 13.5 18.891 36.5187 0.08 0.02 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-19 55 nd 36.2441 -55.6084 33.6 18.735 36.5167 0.06 0.02 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-20 59 nd 36.4882 -52.2773 28.5 18.463 36.5099 0.12 0.01 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-20 59 nd 36.4882 -52.2773 103.6 17.709 36.4947 3.03 0.15 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-21 60 nd 36.6472 -51.4392 153.7 17.479 36.4393 3.07 0.15 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-21 60 nd 36.6472 -51.4392 203.4 16.94 36.3529 6.19 0.33 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-22 63 nd 36.2437 -48.9668 39.3 18.817 36.5714 0.02 0.00 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-22 63 nd 36.2437 -48.9668 104.2 18.045 36.5448 3.19 0.14 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-22 64 nd 36.2497 -48.1291 203.8 17.604 36.4701 4.84 0.25 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-22 64 nd 36.2497 -48.1291 303.9 16.661 36.2954 8.27 0.44 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-23 65 nd 36.2645 -47.3102 12.7 18.733 36.5524 0.29 0.00 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-23 66 nd 36.248 -46.4699 153.3 18.069 36.5832 2.49 0.09 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-23 66 nd 36.248 -46.4699 203.2 17.967 36.5712 3.10 0.11 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-23 66 nd 36.248 -46.4699 302.8 17.973 36.5912 2.93 0.11 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-23 66 nd 36.248 -46.4699 402.9 17.632 36.5074 4.81 0.23 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-23 66 nd 36.248 -46.4699 552.8 15.539 36.1646 6.46 0.36 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-24 67 nd 36.2508 -45.6552 13.2 18.952 36.5358 0.00 0.01 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-24 67 nd 36.2508 -45.6552 23.3 18.579 36.5806 0.02 0.02 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-24 67 nd 36.2508 -45.6552 103.2 18.256 36.5766 1.51 0.09 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-24 68 nd 36.2534 -44.8246 203 18.037 36.5754 3.05 0.16 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-25 71 nd 36.247 -42.5433 12.8 19.71 36.461 0.03 0.01 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-25 71 nd 36.247 -42.5433 37.7 18.687 36.4638 0.05 0.00 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-26 75 nd 36.2521 -40.0992 153.5 17.445 36.4195 3.72 0.19 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-27 77 nd 36.249 -38.8635 13.3 19.38 36.4944 0.03 0.00 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-27 77 nd 36.249 -38.8635 38.3 18.594 36.4721 0.10 0.00 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-27 77 nd 36.249 -38.8635 103.5 17.398 36.4 2.81 0.13 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-27 78 nd 36.2434 -38.2691 203.2 16.821 36.3291 4.62 0.24 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-27 78 nd 36.2434 -38.2691 303.1 15.472 36.0942 7.91 0.45 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-27 78 nd 36.2434 -38.2691 402.9 14.399 35.9363 9.99 0.57 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-27 78 nd 36.2434 -38.2691 552.4 12.475 35.6621 13.33 0.79 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-28 81 nd 36.2492 -36.432 11.8 19.709 36.4704 0.00 0.03 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-28 81 nd 36.2492 -36.432 102.4 17.297 36.3674 3.72 0.22 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-28 82 nd 36.2495 -35.8153 152.3 16.904 36.32 3.59 0.21 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-29 86 nd 36.2516 -33.3682 12 19.996 36.6332 0.00 0.00 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-29 86 nd 36.2516 -33.3682 46.9 19.002 36.6074 0.01 0.00 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-29 86 nd 36.2516 -33.3682 101.9 18.596 36.5682 1.08 0.04 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-29 87 nd 36.2473 -32.7616 152.1 17.907 36.4626 2.88 0.13 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-29 87 nd 36.2473 -32.7616 202.1 17.404 36.3929 4.17 0.21 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-29 87 nd 36.2473 -32.7616 302.1 16.313 36.2448 3.63 0.19 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-29 87 nd 36.2473 -32.7616 402.2 14.623 35.9657 9.23 0.53 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-29 87 nd 36.2473 -32.7616 702.2 10.053 35.3717 20.10 1.23 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-29 87 nd 36.2473 -32.7616 1002.4 8.608 35.5507 18.71 1.15 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-29 87 nd 36.2473 -32.7616 1602.5 4.916 35.1198 18.36 1.15 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-29 87 nd 36.2473 -32.7616 2216.5 3.497 34.9671 17.95 1.17 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-30 89 nd 36.2473 -31.5319 12.8 19.298 36.3251 0.02 0.00 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-30 89 nd 36.2473 -31.5319 52.8 17.794 36.3228 0.09 0.00 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-30 90 nd 36.246 -30.9347 102.6 16.788 36.3169 3.39 0.18 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-30 90 nd 36.246 -30.9347 151.7 16.229 36.2388 5.53 0.30 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-30 90 nd 36.246 -30.9347 202.8 15.559 36.1278 7.24 0.40 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-30 90 nd 36.246 -30.9347 302.8 13.981 35.8822 9.51 0.55 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-30 90 nd 36.246 -30.9347 552.8 11.48 35.5592 15.14 0.91 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-31 94 nd 36.2483 -28.4851 47.9 16.83 36.2111 0.00 0.03 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-31 94 nd 36.2483 -28.4851 102.9 16.429 36.2539 3.09 0.19 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-31 95 nd 36.2406 -27.8352 202.9 15.619 36.1554 5.92 0.36 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-31 95 nd 36.2406 -27.8352 302.5 14.11 35.9033 9.62 0.58 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-05-31 95 nd 36.2406 -27.8352 403 13.106 35.7573 12.25 0.73 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-01 97 nd 36.2521 -26.651 14.3 19.224 36.2566 0.02 0.01 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-01 97 nd 36.2521 -26.651 64.4 16.48 36.1984 0.09 0.02 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-01 97 nd 36.2521 -26.651 104.4 15.604 36.1663 3.56 0.21 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-01 98 nd 36.2502 -26.0339 304.1 13.305 35.7889 10.55 0.61 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-01 98 nd 36.2502 -26.0339 404.3 12.252 35.6424 13.01 0.77 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-01 98 nd 36.2502 -26.0339 553.9 10.944 35.5067 16.61 0.98 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-01 98 nd 36.2502 -26.0339 2004.5 3.506 34.9667 18.91 1.18 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-03 101 nd 36.2478 -25.4195 12.6 19.176 36.3243 0.00 0.00 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-03 101 nd 36.2478 -25.4195 62.6 17.442 36.2866 0.02 0.01 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-03 102 nd 36.2502 -24.8167 152.6 15.596 36.1879 4.24 0.24 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-03 102 nd 36.2502 -24.8167 2003.7 3.389 34.9353 17.91 1.17 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-04 105 nd 36.2491 -22.9808 15.2 18.494 36.264 0.02 0.00 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-04 105 nd 36.2491 -22.9808 45.2 17.239 36.2294 0.03 0.00 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-04 106 nd 36.25 -22.355 305.2 13.894 35.8857 8.77 0.51 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-05 108 nd 36.249 -21.1515 14.1 18.73 36.3239 0.00 0.00 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-05 108 nd 36.249 -21.1515 54.1 16.093 36.1424 0.08 0.01 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-05 108 nd 36.249 -21.1515 104 15.249 36.1213 3.80 0.23 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-05 109 nd 36.2495 -20.5278 204 14.63 36.0653 5.38 0.32 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-05 110 nd 36.251 -19.9136 14.2 19.236 36.3994 0.00 0.00 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-05 110 nd 36.251 -19.9136 69.1 16.092 36.1879 0.04 0.01 0.21 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-05 110 nd 36.251 -19.9136 104.2 15.49 36.2114 3.68 0.23 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-07 114 nd 36.255 -17.4666 15.9 18.893 36.3674 0.05 0.01 0.07 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-07 114 nd 36.255 -17.4666 41 18.812 36.364 0.13 0.00 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-07 114 nd 36.255 -17.4666 105.9 15.728 36.2552 4.54 0.25 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-07 115 nd 36.2586 -16.86 206.3 14.392 36.023 6.78 0.40 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-07 115 nd 36.2586 -16.86 306.2 14.027 36.0134 6.91 0.41 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-07 115 nd 36.2586 -16.86 405.9 13.204 35.8596 8.46 0.50 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-08 118 nd 36.1506 -15.3708 12 19.06 36.559 0.05 0.00 0.08 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-08 118 nd 36.1506 -15.3708 102.1 15.903 36.2552 2.73 0.17 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-08 119 nd 35.9932 -14.9583 152.1 15.294 36.1965 4.92 0.29 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-08 119 nd 35.9932 -14.9583 401.7 12.627 35.7042 12.24 0.73 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-08 120 nd 35.9005 -14.701 12.6 19.109 36.6044 0.01 0.00 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-08 120 nd 35.9005 -14.701 52.3 17.646 36.4481 0.00 0.00 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-08 120 nd 35.9005 -14.701 102.8 16.216 36.3412 3.83 0.21 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-09 121 nd 35.7929 -13.9904 152.8 15.505 36.2269 4.93 0.28 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-09 121 nd 35.7929 -13.9904 202.9 15.005 36.1413 5.67 0.32 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-09 121 nd 35.7929 -13.9904 302.8 14.022 36.0032 6.78 0.39 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-09 121 nd 35.7929 -13.9904 3001.9 2.795 34.9472 21.55 1.45 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-10 124 nd 35.8002 -11.8989 104.3 16.275 36.3952 3.58 0.21 0.06 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-10 125 nd 35.8092 -11.1937 154 15.537 36.268 4.96 0.29 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-10 125 nd 35.8092 -11.1937 203.7 15.036 36.1694 5.73 0.33 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-10 126 nd 35.7957 -10.495 14.9 20.007 36.5047 0.00 0.00 0.10 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-10 126 nd 35.7957 -10.495 44.9 16.168 36.1934 0.00 0.02 0.09 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-10 126 nd 35.7957 -10.495 104.5 14.366 36.0839 6.79 0.39 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-11 127 nd 35.8988 -9.80384 203.7 13.562 35.9467 8.07 0.48 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-11 127 nd 35.8988 -9.80384 303.9 12.717 35.7986 10.76 0.64 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-12 134 nd 36.5953 -8.67737 11.9 19.578 36.4621 0.00 0.01 0.04 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-12 134 nd 36.5953 -8.67737 35 16.209 36.3064 0.00 0.04 0.05 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-12 135 nd 36.6395 -8.66133 101.8 14.921 36.1713 5.96 0.36 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-12 135 nd 36.6395 -8.66133 151.9 14.802 36.1583 6.25 0.38 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-12 135 nd 36.6395 -8.66133 301.8 12.702 35.7278 12.69 0.74 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-12 135 nd 36.6395 -8.66133 701.6 12.441 36.3479 13.37 0.77 0.01 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-12 135 nd 36.6395 -8.66133 761 12.799 36.5081 12.28 0.70 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-13 140 nd 35.0493 -8.06395 32.7 18.536 36.4191 0.06 0.01 0.03 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-13 141 nd 34.5829 -7.82029 801.7 10.483 35.7607 18.59 1.14 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd 36N 2005-06-13 141 nd 34.5829 -7.82029 1100.7 9.818 35.9228 18.42 1.13 0.02 2 North Atlantic UV oxidation Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in the North and South Atlantic Ocean subtropical gyres. Nature Geosci 1; 439 443 (2008). https://doi.org/10.1038/ngeo232 nd SATL2004 nd nd nd 20.03 -19.27 1 nd nd nd nd 0.26 2 North Atlantic Wet oxidation Reinthaler; Thomas; Sintes; Eva; Herndl; Gerhard J.; (2008); Dissolved organic matter and bacterial production and respiration in the sea surface microlayer of the open Atlantic and the western Mediterranean Sea; Limnology and Oceanography; 53; doi: 10.4319/lo.2008.53.1.0122. nd SATL2004 nd nd nd 20.03 -19.27 1 nd nd nd nd 0.31 2 North Atlantic Wet oxidation Reinthaler; Thomas; Sintes; Eva; Herndl; Gerhard J.; (2008); Dissolved organic matter and bacterial production and respiration in the sea surface microlayer of the open Atlantic and the western Mediterranean Sea; Limnology and Oceanography; 53; doi: 10.4319/lo.2008.53.1.0122. nd SATL2004 nd nd nd 20.69 -24.06 1 nd nd nd nd 0.25 2 North Atlantic Wet oxidation Reinthaler; Thomas; Sintes; Eva; Herndl; Gerhard J.; (2008); Dissolved organic matter and bacterial production and respiration in the sea surface microlayer of the open Atlantic and the western Mediterranean Sea; Limnology and Oceanography; 53; doi: 10.4319/lo.2008.53.1.0122. nd SATL2004 nd nd nd 20.69 -24.06 1 nd nd nd nd 0.23 2 North Atlantic Wet oxidation Reinthaler; Thomas; Sintes; Eva; Herndl; Gerhard J.; (2008); Dissolved organic matter and bacterial production and respiration in the sea surface microlayer of the open Atlantic and the western Mediterranean Sea; Limnology and Oceanography; 53; doi: 10.4319/lo.2008.53.1.0122. nd SATL2004 nd nd nd 20.69 -24.06 1 nd nd nd nd 0.23 2 North Atlantic Wet oxidation Reinthaler; Thomas; Sintes; Eva; Herndl; Gerhard J.; (2008); Dissolved organic matter and bacterial production and respiration in the sea surface microlayer of the open Atlantic and the western Mediterranean Sea; Limnology and Oceanography; 53; doi: 10.4319/lo.2008.53.1.0122. nd SATL2004 nd nd nd 21.77 -26.71 1 nd nd nd nd 0.23 2 North Atlantic Wet oxidation Reinthaler; Thomas; Sintes; Eva; Herndl; Gerhard J.; (2008); Dissolved organic matter and bacterial production and respiration in the sea surface microlayer of the open Atlantic and the western Mediterranean Sea; Limnology and Oceanography; 53; doi: 10.4319/lo.2008.53.1.0122. nd SATL2004 nd nd nd 21.77 -26.71 1 nd nd nd nd 0.19 2 North Atlantic Wet oxidation Reinthaler; Thomas; Sintes; Eva; Herndl; Gerhard J.; (2008); Dissolved organic matter and bacterial production and respiration in the sea surface microlayer of the open Atlantic and the western Mediterranean Sea; Limnology and Oceanography; 53; doi: 10.4319/lo.2008.53.1.0122. nd SATL2004 nd nd nd 21.76 -26.64 1 nd nd nd nd 0.20 2 North Atlantic Wet oxidation Reinthaler; Thomas; Sintes; Eva; Herndl; Gerhard J.; (2008); Dissolved organic matter and bacterial production and respiration in the sea surface microlayer of the open Atlantic and the western Mediterranean Sea; Limnology and Oceanography; 53; doi: 10.4319/lo.2008.53.1.0122. nd SATL2004 nd nd nd 21.71 -26.65 1 nd nd nd nd 0.21 2 North Atlantic Wet oxidation Reinthaler; Thomas; Sintes; Eva; Herndl; Gerhard J.; (2008); Dissolved organic matter and bacterial production and respiration in the sea surface microlayer of the open Atlantic and the western Mediterranean Sea; Limnology and Oceanography; 53; doi: 10.4319/lo.2008.53.1.0122. nd SATL2004 nd nd nd 23 -29.39 1 nd nd nd nd 0.18 2 North Atlantic Wet oxidation Reinthaler; Thomas; Sintes; Eva; Herndl; Gerhard J.; (2008); Dissolved organic matter and bacterial production and respiration in the sea surface microlayer of the open Atlantic and the western Mediterranean Sea; Limnology and Oceanography; 53; doi: 10.4319/lo.2008.53.1.0122. nd SATL2004 nd nd nd 22.97 -29.43 1 nd nd nd nd 0.21 2 North Atlantic Wet oxidation Reinthaler; Thomas; Sintes; Eva; Herndl; Gerhard J.; (2008); Dissolved organic matter and bacterial production and respiration in the sea surface microlayer of the open Atlantic and the western Mediterranean Sea; Limnology and Oceanography; 53; doi: 10.4319/lo.2008.53.1.0122. nd SATL2004 nd nd nd 22.99 -29.44 1 nd nd nd nd 0.17 2 North Atlantic Wet oxidation Reinthaler; Thomas; Sintes; Eva; Herndl; Gerhard J.; (2008); Dissolved organic matter and bacterial production and respiration in the sea surface microlayer of the open Atlantic and the western Mediterranean Sea; Limnology and Oceanography; 53; doi: 10.4319/lo.2008.53.1.0122. nd SATL2004 nd nd nd 24.6 -31.24 1 nd nd nd nd 0.14 2 North Atlantic Wet oxidation Reinthaler; Thomas; Sintes; Eva; Herndl; Gerhard J.; (2008); Dissolved organic matter and bacterial production and respiration in the sea surface microlayer of the open Atlantic and the western Mediterranean Sea; Limnology and Oceanography; 53; doi: 10.4319/lo.2008.53.1.0122. nd SATL2004 nd nd nd 24.58 -31.24 1 nd nd nd nd 0.15 2 North Atlantic Wet oxidation Reinthaler; Thomas; Sintes; Eva; Herndl; Gerhard J.; (2008); Dissolved organic matter and bacterial production and respiration in the sea surface microlayer of the open Atlantic and the western Mediterranean Sea; Limnology and Oceanography; 53; doi: 10.4319/lo.2008.53.1.0122. nd SATL2004 nd nd nd 24.57 -31.23 1 nd nd nd nd 0.15 2 North Atlantic Wet oxidation Reinthaler; Thomas; Sintes; Eva; Herndl; Gerhard J.; (2008); Dissolved organic matter and bacterial production and respiration in the sea surface microlayer of the open Atlantic and the western Mediterranean Sea; Limnology and Oceanography; 53; doi: 10.4319/lo.2008.53.1.0122. nd SATL2004 nd nd nd 24.49 -31.25 1 nd nd nd nd 0.13 2 North Atlantic Wet oxidation Reinthaler; Thomas; Sintes; Eva; Herndl; Gerhard J.; (2008); Dissolved organic matter and bacterial production and respiration in the sea surface microlayer of the open Atlantic and the western Mediterranean Sea; Limnology and Oceanography; 53; doi: 10.4319/lo.2008.53.1.0122. nd SATL2004 nd nd nd 24.47 -31.26 1 nd nd nd nd 0.12 2 North Atlantic Wet oxidation Reinthaler; Thomas; Sintes; Eva; Herndl; Gerhard J.; (2008); Dissolved organic matter and bacterial production and respiration in the sea surface microlayer of the open Atlantic and the western Mediterranean Sea; Limnology and Oceanography; 53; doi: 10.4319/lo.2008.53.1.0122. nd KM0415 nd nd nd 30.8 -169.5 10 nd nd nd nd 0.10 2 North Pacific Wet oxidation Yoshimura; T.; Nishioka; J.; Saito; H.; Takeda; S.; Tsuda; A.; & Wells; M. L. (2007). Distributions of particulate and dissolved organic and inorganic phosphorus in North Pacific surface waters. Marine chemistry; 103(1-2); 112-121.; https://doi.org/10.1016/j.marchem.2006.06.011 nd KM0415 nd nd nd 31.5 -170.4 10 nd nd nd nd 0.10 2 North Pacific Wet oxidation Yoshimura; T.; Nishioka; J.; Saito; H.; Takeda; S.; Tsuda; A.; & Wells; M. L. (2007). Distributions of particulate and dissolved organic and inorganic phosphorus in North Pacific surface waters. Marine chemistry; 103(1-2); 112-121.; https://doi.org/10.1016/j.marchem.2006.06.011 nd KM0415 nd nd nd 33.4 -172.8 10 nd nd nd nd 0.12 2 North Pacific Wet oxidation Yoshimura; T.; Nishioka; J.; Saito; H.; Takeda; S.; Tsuda; A.; & Wells; M. L. (2007). Distributions of particulate and dissolved organic and inorganic phosphorus in North Pacific surface waters. Marine chemistry; 103(1-2); 112-121.; https://doi.org/10.1016/j.marchem.2006.06.011 nd KM0415 nd nd nd 33.9 -173.4 10 nd nd nd nd 0.13 2 North Pacific Wet oxidation Yoshimura; T.; Nishioka; J.; Saito; H.; Takeda; S.; Tsuda; A.; & Wells; M. L. (2007). Distributions of particulate and dissolved organic and inorganic phosphorus in North Pacific surface waters. Marine chemistry; 103(1-2); 112-121.; https://doi.org/10.1016/j.marchem.2006.06.011 nd KM0415 nd nd nd 34.6 -174.3 10 nd nd nd nd 0.12 2 North Pacific Wet oxidation Yoshimura; T.; Nishioka; J.; Saito; H.; Takeda; S.; Tsuda; A.; & Wells; M. L. (2007). Distributions of particulate and dissolved organic and inorganic phosphorus in North Pacific surface waters. Marine chemistry; 103(1-2); 112-121.; https://doi.org/10.1016/j.marchem.2006.06.011 nd KM0415 nd nd nd 36.5 -176.8 10 nd nd nd nd 0.14 2 North Pacific Wet oxidation Yoshimura; T.; Nishioka; J.; Saito; H.; Takeda; S.; Tsuda; A.; & Wells; M. L. (2007). Distributions of particulate and dissolved organic and inorganic phosphorus in North Pacific surface waters. Marine chemistry; 103(1-2); 112-121.; https://doi.org/10.1016/j.marchem.2006.06.011 nd KM0415 nd nd nd 36.8 -177.2 10 nd nd nd nd 0.12 2 North Pacific Wet oxidation Yoshimura; T.; Nishioka; J.; Saito; H.; Takeda; S.; Tsuda; A.; & Wells; M. L. (2007). Distributions of particulate and dissolved organic and inorganic phosphorus in North Pacific surface waters. Marine chemistry; 103(1-2); 112-121.; https://doi.org/10.1016/j.marchem.2006.06.011 nd KM0415 nd nd nd 37.5 -178.2 10 nd nd nd nd 0.13 2 North Pacific Wet oxidation Yoshimura; T.; Nishioka; J.; Saito; H.; Takeda; S.; Tsuda; A.; & Wells; M. L. (2007). Distributions of particulate and dissolved organic and inorganic phosphorus in North Pacific surface waters. Marine chemistry; 103(1-2); 112-121.; https://doi.org/10.1016/j.marchem.2006.06.011 nd KM0415 nd nd nd 39.5 179.1 10 nd nd nd nd 0.16 2 North Pacific Wet oxidation Yoshimura; T.; Nishioka; J.; Saito; H.; Takeda; S.; Tsuda; A.; & Wells; M. L. (2007). Distributions of particulate and dissolved organic and inorganic phosphorus in North Pacific surface waters. Marine chemistry; 103(1-2); 112-121.; https://doi.org/10.1016/j.marchem.2006.06.011 nd KM0415 nd nd nd 39.9 178.4 10 nd nd nd nd 0.16 2 North Pacific Wet oxidation Yoshimura; T.; Nishioka; J.; Saito; H.; Takeda; S.; Tsuda; A.; & Wells; M. L. (2007). Distributions of particulate and dissolved organic and inorganic phosphorus in North Pacific surface waters. Marine chemistry; 103(1-2); 112-121.; https://doi.org/10.1016/j.marchem.2006.06.011 nd KM0415 nd nd nd 40.3 177.8 10 nd nd nd nd 0.17 2 North Pacific Wet oxidation Yoshimura; T.; Nishioka; J.; Saito; H.; Takeda; S.; Tsuda; A.; & Wells; M. L. (2007). Distributions of particulate and dissolved organic and inorganic phosphorus in North Pacific surface waters. Marine chemistry; 103(1-2); 112-121.; https://doi.org/10.1016/j.marchem.2006.06.011 nd KM0415 nd nd nd 41 177 10 nd nd nd nd 0.10 2 North Pacific Wet oxidation Yoshimura; T.; Nishioka; J.; Saito; H.; Takeda; S.; Tsuda; A.; & Wells; M. L. (2007). Distributions of particulate and dissolved organic and inorganic phosphorus in North Pacific surface waters. Marine chemistry; 103(1-2); 112-121.; https://doi.org/10.1016/j.marchem.2006.06.011 nd KM0415 nd nd nd 42.4 174.9 10 nd nd nd nd 0.12 2 North Pacific Wet oxidation Yoshimura; T.; Nishioka; J.; Saito; H.; Takeda; S.; Tsuda; A.; & Wells; M. L. (2007). Distributions of particulate and dissolved organic and inorganic phosphorus in North Pacific surface waters. Marine chemistry; 103(1-2); 112-121.; https://doi.org/10.1016/j.marchem.2006.06.011 nd KM0415 nd nd nd 42.9 174.1 10 nd nd nd nd 0.17 2 North Pacific Wet oxidation Yoshimura; T.; Nishioka; J.; Saito; H.; Takeda; S.; Tsuda; A.; & Wells; M. L. (2007). Distributions of particulate and dissolved organic and inorganic phosphorus in North Pacific surface waters. Marine chemistry; 103(1-2); 112-121.; https://doi.org/10.1016/j.marchem.2006.06.011 nd KM0415 nd nd nd 43.6 173.1 10 nd nd nd nd 0.19 2 North Pacific Wet oxidation Yoshimura; T.; Nishioka; J.; Saito; H.; Takeda; S.; Tsuda; A.; & Wells; M. L. (2007). Distributions of particulate and dissolved organic and inorganic phosphorus in North Pacific surface waters. Marine chemistry; 103(1-2); 112-121.; https://doi.org/10.1016/j.marchem.2006.06.011 nd KM0415 nd nd nd 45.5 170.2 10 nd nd nd nd 0.19 2 North Pacific Wet oxidation Yoshimura; T.; Nishioka; J.; Saito; H.; Takeda; S.; Tsuda; A.; & Wells; M. L. (2007). Distributions of particulate and dissolved organic and inorganic phosphorus in North Pacific surface waters. Marine chemistry; 103(1-2); 112-121.; https://doi.org/10.1016/j.marchem.2006.06.011 nd KM0415 nd nd nd 46 169.5 10 nd nd nd nd 0.13 2 North Pacific Wet oxidation Yoshimura; T.; Nishioka; J.; Saito; H.; Takeda; S.; Tsuda; A.; & Wells; M. L. (2007). Distributions of particulate and dissolved organic and inorganic phosphorus in North Pacific surface waters. Marine chemistry; 103(1-2); 112-121.; https://doi.org/10.1016/j.marchem.2006.06.011 nd KM0415 nd nd nd 46.2 168.9 10 nd nd nd nd 0.14 2 North Pacific Wet oxidation Yoshimura; T.; Nishioka; J.; Saito; H.; Takeda; S.; Tsuda; A.; & Wells; M. L. (2007). Distributions of particulate and dissolved organic and inorganic phosphorus in North Pacific surface waters. Marine chemistry; 103(1-2); 112-121.; https://doi.org/10.1016/j.marchem.2006.06.011 nd KM0415 nd nd nd 47.9 166.4 10 nd nd nd nd 0.21 2 North Pacific Wet oxidation Yoshimura; T.; Nishioka; J.; Saito; H.; Takeda; S.; Tsuda; A.; & Wells; M. L. (2007). Distributions of particulate and dissolved organic and inorganic phosphorus in North Pacific surface waters. Marine chemistry; 103(1-2); 112-121.; https://doi.org/10.1016/j.marchem.2006.06.011 nd Line P nd nd nd 48.65 -126.67 2 nd nd nd nd 0.29 2 North Pacific UV oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 48.65 -126.67 10 nd nd nd nd 0.24 2 North Pacific UV oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 49.57 -138.67 10 nd nd nd nd 0.19 2 North Pacific UV oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 49.57 -138.67 50 nd nd nd nd 0.17 2 North Pacific UV oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 49.57 -138.67 100 nd nd nd nd 0.06 2 North Pacific UV oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 49.57 -138.67 200 nd nd nd nd 0.08 2 North Pacific UV oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 49.57 -138.67 400 nd nd nd nd 0.07 2 North Pacific UV oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 49.57 -138.67 800 nd nd nd nd 0.07 2 North Pacific UV oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 49.57 -138.67 3800 nd nd nd nd 0.01 2 North Pacific UV oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 50 -145 10 nd nd nd nd 0.14 2 North Pacific UV oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 50 -145 50 nd nd nd nd 0.13 2 North Pacific UV oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 50 -145 70 nd nd nd nd 0.11 2 North Pacific UV oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 50 -145 100 nd nd nd nd 0.11 2 North Pacific UV oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 50 -145 200 nd nd nd nd 0.10 2 North Pacific UV oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 50 -145 400 nd nd nd nd 0.06 2 North Pacific UV oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 50 -145 800 nd nd nd nd 0.02 2 North Pacific UV oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 50 -145 1200 nd nd nd nd 0.05 2 North Pacific UV oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 50 -145 2000 nd nd nd nd 0.01 2 North Pacific UV oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 48.65 -126.67 2 nd nd nd nd 0.33 2 North Pacific Wet oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 48.65 -126.67 10 nd nd nd nd 0.33 2 North Pacific Wet oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 49.57 -138.67 10 nd nd nd nd 0.21 2 North Pacific Wet oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 49.57 -138.67 50 nd nd nd nd 0.21 2 North Pacific Wet oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 49.57 -138.67 100 nd nd nd nd 0.12 2 North Pacific Wet oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 49.57 -138.67 200 nd nd nd nd 0.06 2 North Pacific Wet oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 49.57 -138.67 400 nd nd nd nd 0.05 2 North Pacific Wet oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 49.57 -138.67 800 nd nd nd nd 0.08 2 North Pacific Wet oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 49.57 -138.67 2000 nd nd nd nd 0.05 2 North Pacific Wet oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 49.57 -138.67 3800 nd nd nd nd 0.03 2 North Pacific Wet oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 50 -145 10 nd nd nd nd 0.18 2 North Pacific Wet oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 50 -145 50 nd nd nd nd 0.14 2 North Pacific Wet oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 50 -145 70 nd nd nd nd 0.08 2 North Pacific Wet oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 50 -145 100 nd nd nd nd 0.11 2 North Pacific Wet oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 50 -145 200 nd nd nd nd 0.08 2 North Pacific Wet oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 50 -145 400 nd nd nd nd 0.04 2 North Pacific Wet oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 50 -145 800 nd nd nd nd 0.04 2 North Pacific Wet oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 50 -145 1200 nd nd nd nd 0.04 2 North Pacific Wet oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Line P nd nd nd 50 -145 2000 nd nd nd nd 0.04 2 North Pacific Wet oxidation Ridal; Jefrey J.; Moore; Robert M.; (1992); Dissolved organic phosphorus concentrations in the northeast subarctic Pacific Ocean; Limnology and Oceanography; 37; doi: 10.4319/lo.1992.37.5.1067. nd Latitude II nd nd nd 25.168 -19.048 5 nd nd nd nd 0.17 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 25.168 -19.048 80 nd nd nd nd 0.19 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 25.168 -19.048 90 nd nd nd nd 0.12 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 25.168 -19.048 125 nd nd nd nd 0.14 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 22.252 -18.254 5 nd nd nd nd 0.11 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 22.252 -18.254 20 nd nd nd nd 0.17 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 22.252 -18.254 40 nd nd nd nd 0.24 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 22.252 -18.254 80 nd nd nd nd 0.25 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 22.252 -18.254 100 nd nd nd nd 0.23 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 22.252 -18.254 150 nd nd nd nd 0.24 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 19.835 -18.259 5 nd nd nd nd 0.20 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 19.835 -18.259 25 nd nd nd nd 0.24 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 19.835 -18.259 40 nd nd nd nd 0.22 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 19.835 -18.259 60 nd nd nd nd 0.29 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 19.835 -18.259 80 nd nd nd nd 0.28 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 19.835 -18.259 100 nd nd nd nd 0.27 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 17.419 -18.248 5 nd nd nd nd 0.15 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 17.419 -18.248 40 nd nd nd nd 0.35 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 17.419 -18.248 60 nd nd nd nd 0.23 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 17.419 -18.248 100 nd nd nd nd 0.25 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 14.764 -17.998 5 nd nd nd nd 0.25 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 14.001 -19.002 5 nd nd nd nd 0.25 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 11.308 -20.438 5 nd nd nd nd 0.16 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 11.308 -20.438 20 nd nd nd nd 0.19 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 11.308 -20.438 40 nd nd nd nd 0.17 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 11.308 -20.438 45 nd nd nd nd 0.22 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 11.308 -20.438 50 nd nd nd nd 0.18 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 11.308 -20.438 60 nd nd nd nd 0.27 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 11.308 -20.438 70 nd nd nd nd 0.23 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 11.308 -20.438 80 nd nd nd nd 0.22 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 11.308 -20.438 100 nd nd nd nd 0.21 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 11.308 -20.438 150 nd nd nd nd 0.26 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 11.308 -20.438 400 nd nd nd nd 0.04 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 7.768 -21.735 5 nd nd nd nd 0.22 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 4.198 -23.207 5 nd nd nd nd 0.16 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 4.198 -23.207 10 nd nd nd nd 0.17 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 4.198 -23.207 20 nd nd nd nd 0.20 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 4.198 -23.207 30 nd nd nd nd 0.29 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 4.198 -23.207 40 nd nd nd nd 0.21 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 4.198 -23.207 50 nd nd nd nd 0.13 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 4.198 -23.207 60 nd nd nd nd 0.26 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 4.198 -23.207 70 nd nd nd nd 0.29 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 4.198 -23.207 80 nd nd nd nd 0.11 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 4.198 -23.207 90 nd nd nd nd 0.15 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 4.198 -23.207 100 nd nd nd nd 0.13 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 4.198 -23.207 125 nd nd nd nd 0.22 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 4.198 -23.207 150 nd nd nd nd 0.15 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 0.945 -24.412 5 nd nd nd nd 0.16 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 0.945 -24.412 10 nd nd nd nd 0.19 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 0.945 -24.412 20 nd nd nd nd 0.16 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 0.945 -24.412 30 nd nd nd nd 0.15 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 0.945 -24.412 40 nd nd nd nd 0.15 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 0.945 -24.412 55 nd nd nd nd 0.15 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 0.945 -24.412 65 nd nd nd nd 0.12 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 0.945 -24.412 80 nd nd nd nd 0.12 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 0.945 -24.412 90 nd nd nd nd 0.17 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 0.945 -24.412 100 nd nd nd nd 0.12 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd 0.945 -24.412 125 nd nd nd nd 0.22 2 North Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -0.072 -24.722 5 nd nd nd nd 0.10 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -0.072 -24.722 10 nd nd nd nd 0.17 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -0.072 -24.722 20 nd nd nd nd 0.14 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -0.072 -24.722 30 nd nd nd nd 0.12 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -0.072 -24.722 40 nd nd nd nd 0.13 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -0.072 -24.722 55 nd nd nd nd 0.16 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -0.072 -24.722 70 nd nd nd nd 0.07 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -0.072 -24.722 80 nd nd nd nd 0.08 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -0.072 -24.722 100 nd nd nd nd 0.07 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -0.072 -24.722 150 nd nd nd nd 0.12 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -2.989 -26.216 5 nd nd nd nd 0.11 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -2.989 -26.216 10 nd nd nd nd 0.14 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -2.989 -26.216 20 nd nd nd nd 0.11 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -2.989 -26.216 30 nd nd nd nd 0.17 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -2.989 -26.216 40 nd nd nd nd 0.11 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -2.989 -26.216 50 nd nd nd nd 0.10 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -2.989 -26.216 60 nd nd nd nd 0.13 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -2.989 -26.216 70 nd nd nd nd 0.17 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -2.989 -26.216 80 nd nd nd nd 0.10 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -2.989 -26.216 90 nd nd nd nd 0.10 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -2.989 -26.216 200 nd nd nd nd 0.08 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -8.803 -28.295 5 nd nd nd nd 0.14 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -8.803 -28.295 10 nd nd nd nd 0.21 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -8.803 -28.295 20 nd nd nd nd 0.15 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -8.803 -28.295 30 nd nd nd nd 0.08 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -8.803 -28.295 40 nd nd nd nd 0.15 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -8.803 -28.295 50 nd nd nd nd 0.10 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -8.803 -28.295 60 nd nd nd nd 0.15 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -8.803 -28.295 80 nd nd nd nd 0.14 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -8.803 -28.295 95 nd nd nd nd 0.14 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -8.803 -28.295 105 nd nd nd nd 0.11 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -8.803 -28.295 115 nd nd nd nd 0.08 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -8.803 -28.295 125 nd nd nd nd 0.12 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -8.803 -28.295 150 nd nd nd nd 0.09 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -11.994 -29.738 5 nd nd nd nd 0.09 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -11.994 -29.738 10 nd nd nd nd 0.16 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -11.994 -29.738 20 nd nd nd nd 0.14 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -11.994 -29.738 30 nd nd nd nd 0.19 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -11.994 -29.738 45 nd nd nd nd 0.05 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -11.994 -29.738 60 nd nd nd nd 0.12 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -11.994 -29.738 90 nd nd nd nd 0.17 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -11.994 -29.738 110 nd nd nd nd 0.17 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -11.994 -29.738 120 nd nd nd nd 0.23 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -11.994 -29.738 130 nd nd nd nd 0.34 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -11.994 -29.738 140 nd nd nd nd 0.25 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -11.994 -29.738 150 nd nd nd nd 0.27 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -14.982 -31.035 15 nd nd nd nd 0.08 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -14.982 -31.035 30 nd nd nd nd 0.07 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -14.982 -31.035 45 nd nd nd nd 0.09 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -14.982 -31.035 60 nd nd nd nd 0.14 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -14.982 -31.035 75 nd nd nd nd 0.17 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -14.982 -31.035 90 nd nd nd nd 0.19 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -14.982 -31.035 105 nd nd nd nd 0.15 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -14.982 -31.035 125 nd nd nd nd 0.21 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -14.982 -31.035 135 nd nd nd nd 0.09 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -14.982 -31.035 150 nd nd nd nd 0.15 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -14.982 -31.035 175 nd nd nd nd 0.17 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -17.903 -32.219 5 nd nd nd nd 0.02 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -17.903 -32.219 10 nd nd nd nd 0.08 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -17.903 -32.219 35 nd nd nd nd 0.01 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -17.903 -32.219 60 nd nd nd nd 0.10 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -17.903 -32.219 110 nd nd nd nd 0.08 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -17.903 -32.219 125 nd nd nd nd 0.06 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -17.903 -32.219 140 nd nd nd nd 0.13 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -17.903 -32.219 160 nd nd nd nd 0.13 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -17.903 -32.219 170 nd nd nd nd 0.04 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -17.903 -32.219 180 nd nd nd nd 0.07 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -17.903 -32.219 200 nd nd nd nd 0.06 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -17.903 -32.219 800 nd nd nd nd 0.01 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -20.8 -33.365 5 nd nd nd nd 0.14 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -20.8 -33.365 10 nd nd nd nd 0.10 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -20.8 -33.365 30 nd nd nd nd 0.27 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -20.8 -33.365 40 nd nd nd nd 0.18 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -20.8 -33.365 60 nd nd nd nd 0.16 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -20.8 -33.365 70 nd nd nd nd 0.12 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -20.8 -33.365 100 nd nd nd nd 0.11 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -20.8 -33.365 130 nd nd nd nd 0.10 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -20.8 -33.365 145 nd nd nd nd 0.09 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -20.8 -33.365 160 nd nd nd nd 0.08 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -20.8 -33.365 175 nd nd nd nd 0.09 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -20.8 -33.365 200 nd nd nd nd 0.08 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -20.8 -33.365 300 nd nd nd nd 0.09 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -20.8 -33.365 400 nd nd nd nd 0.07 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -23.451 -35.751 5 nd nd nd nd 0.12 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -23.451 -35.751 10 nd nd nd nd 0.11 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -23.451 -35.751 30 nd nd nd nd 0.18 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -23.451 -35.751 60 nd nd nd nd 0.16 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -23.451 -35.751 70 nd nd nd nd 0.15 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -23.451 -35.751 85 nd nd nd nd 0.12 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -23.451 -35.751 100 nd nd nd nd 0.15 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -23.451 -35.751 110 nd nd nd nd 0.15 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -23.451 -35.751 120 nd nd nd nd 0.16 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -23.451 -35.751 150 nd nd nd nd 0.13 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -23.451 -35.751 200 nd nd nd nd 0.08 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -23.451 -35.751 800 nd nd nd nd 0.03 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -24.268 -36.346 5 nd nd nd nd 0.08 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -24.268 -36.346 10 nd nd nd nd 0.13 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -24.268 -36.346 30 nd nd nd nd 0.09 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -24.268 -36.346 60 nd nd nd nd 0.09 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -24.268 -36.346 75 nd nd nd nd 0.08 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -24.268 -36.346 90 nd nd nd nd 0.08 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -24.268 -36.346 105 nd nd nd nd 0.11 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -24.268 -36.346 120 nd nd nd nd 0.02 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -24.268 -36.346 140 nd nd nd nd 0.09 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -24.268 -36.346 150 nd nd nd nd 0.05 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -24.268 -36.346 175 nd nd nd nd 0.08 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -24.268 -36.346 200 nd nd nd nd 0.04 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -24.268 -36.346 400 nd nd nd nd 0.06 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -24.268 -36.346 600 nd nd nd nd 0.07 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -26.002 -38.171 25 nd nd nd nd 0.01 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -26.002 -38.171 60 nd nd nd nd 0.03 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -26.002 -38.171 115 nd nd nd nd 0.03 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -26.002 -38.171 125 nd nd nd nd 0.02 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -26.002 -38.171 135 nd nd nd nd 0.07 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -26.002 -38.171 150 nd nd nd nd 0.01 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -26.002 -38.171 400 nd nd nd nd 0.02 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -28.087 -40.143 5 nd nd nd nd 0.04 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -28.087 -40.143 35 nd nd nd nd 0.10 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -28.087 -40.143 50 nd nd nd nd 0.05 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -28.087 -40.143 75 nd nd nd nd 0.07 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -28.087 -40.143 90 nd nd nd nd 0.04 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -28.087 -40.143 105 nd nd nd nd 0.08 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -28.087 -40.143 120 nd nd nd nd 0.11 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -28.087 -40.143 130 nd nd nd nd 0.02 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -28.087 -40.143 140 nd nd nd nd 0.06 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -28.087 -40.143 150 nd nd nd nd 0.01 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -28.087 -40.143 250 nd nd nd nd 0.05 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -28.087 -40.143 600 nd nd nd nd 0.03 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -28.087 -40.143 800 nd nd nd nd 0.01 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -30.577 -42.543 5 nd nd nd nd 0.02 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -30.577 -42.543 10 nd nd nd nd 0.02 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -30.577 -42.543 30 nd nd nd nd 0.10 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -30.577 -42.543 60 nd nd nd nd 0.06 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -30.577 -42.543 90 nd nd nd nd 0.05 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Latitude II nd nd nd -30.577 -42.543 110 nd nd nd nd 0.07 2 South Atlantic Wet oxidation Vidal; Montserrat Duarte; Carlos M. Agusti; Susana; (1999); Dissolved organic nitrogen and phosphorus pools and fluxes in the central Atlantic Ocean; Limnology and Oceanography; 1; doi: 10.4319/lo.1999.44.1.0106. nd Pulse-26 cruise nd nd nd 34.833 -123 25 nd nd nd nd 0.23 2 North Pacific ash/hydrolysis Loh; A. N.; & Bauer; J. E. (2000). Distribution; partitioning and fluxes of dissolved and particulate organic C; N and P in the eastern North Pacific and Southern Oceans. Deep Sea Research Part I: Oceanographic Research Papers; 47(12); 2287-2316.; https://doi.org/10.1016/S0967-0637(00)00027-3 nd Pulse-26 cruise nd nd nd 34.833 -123 85 nd nd nd nd 0.23 2 North Pacific ash/hydrolysis Loh; A. N.; & Bauer; J. E. (2000). Distribution; partitioning and fluxes of dissolved and particulate organic C; N and P in the eastern North Pacific and Southern Oceans. Deep Sea Research Part I: Oceanographic Research Papers; 47(12); 2287-2316.; https://doi.org/10.1016/S0967-0637(00)00027-3 nd Pulse-26 cruise nd nd nd 34.833 -123 1282 nd nd nd nd 0.09 2 North Pacific ash/hydrolysis Loh; A. N.; & Bauer; J. E. (2000). Distribution; partitioning and fluxes of dissolved and particulate organic C; N and P in the eastern North Pacific and Southern Oceans. Deep Sea Research Part I: Oceanographic Research Papers; 47(12); 2287-2316.; https://doi.org/10.1016/S0967-0637(00)00027-3 nd Pulse-26 cruise nd nd nd 34.833 -123 1600 nd nd nd nd 0.09 2 North Pacific ash/hydrolysis Loh; A. N.; & Bauer; J. E. (2000). Distribution; partitioning and fluxes of dissolved and particulate organic C; N and P in the eastern North Pacific and Southern Oceans. Deep Sea Research Part I: Oceanographic Research Papers; 47(12); 2287-2316.; https://doi.org/10.1016/S0967-0637(00)00027-3 nd Pulse-26 cruise nd nd nd 34.833 -123 2515 nd nd nd nd 0.07 2 North Pacific ash/hydrolysis Loh; A. N.; & Bauer; J. E. (2000). Distribution; partitioning and fluxes of dissolved and particulate organic C; N and P in the eastern North Pacific and Southern Oceans. Deep Sea Research Part I: Oceanographic Research Papers; 47(12); 2287-2316.; https://doi.org/10.1016/S0967-0637(00)00027-3 nd Pulse-26 cruise nd nd nd 34.833 -123 3466 nd nd nd nd 0.08 2 North Pacific ash/hydrolysis Loh; A. N.; & Bauer; J. E. (2000). Distribution; partitioning and fluxes of dissolved and particulate organic C; N and P in the eastern North Pacific and Southern Oceans. Deep Sea Research Part I: Oceanographic Research Papers; 47(12); 2287-2316.; https://doi.org/10.1016/S0967-0637(00)00027-3 nd Pulse-26 cruise nd nd nd 35.45 -122.35 22 nd nd nd nd 0.23 2 North Pacific ash/hydrolysis Loh; A. N.; & Bauer; J. E. (2000). Distribution; partitioning and fluxes of dissolved and particulate organic C; N and P in the eastern North Pacific and Southern Oceans. Deep Sea Research Part I: Oceanographic Research Papers; 47(12); 2287-2316.; https://doi.org/10.1016/S0967-0637(00)00027-3 nd Pulse-26 cruise nd nd nd 35.45 -122.35 189 nd nd nd nd 0.13 2 North Pacific ash/hydrolysis Loh; A. N.; & Bauer; J. E. (2000). Distribution; partitioning and fluxes of dissolved and particulate organic C; N and P in the eastern North Pacific and Southern Oceans. Deep Sea Research Part I: Oceanographic Research Papers; 47(12); 2287-2316.; https://doi.org/10.1016/S0967-0637(00)00027-3 nd Pulse-26 cruise nd nd nd 35.45 -122.35 1628 nd nd nd nd 0.10 2 North Pacific ash/hydrolysis Loh; A. N.; & Bauer; J. E. (2000). Distribution; partitioning and fluxes of dissolved and particulate organic C; N and P in the eastern North Pacific and Southern Oceans. Deep Sea Research Part I: Oceanographic Research Papers; 47(12); 2287-2316.; https://doi.org/10.1016/S0967-0637(00)00027-3 nd Pulse-26 cruise nd nd nd 35.45 -122.35 2568 nd nd nd nd 0.09 2 North Pacific ash/hydrolysis Loh; A. N.; & Bauer; J. E. (2000). Distribution; partitioning and fluxes of dissolved and particulate organic C; N and P in the eastern North Pacific and Southern Oceans. Deep Sea Research Part I: Oceanographic Research Papers; 47(12); 2287-2316.; https://doi.org/10.1016/S0967-0637(00)00027-3 nd Pulse-26 cruise nd nd nd 35.45 -122.35 3152 nd nd nd nd 0.08 2 North Pacific ash/hydrolysis Loh; A. N.; & Bauer; J. E. (2000). Distribution; partitioning and fluxes of dissolved and particulate organic C; N and P in the eastern North Pacific and Southern Oceans. Deep Sea Research Part I: Oceanographic Research Papers; 47(12); 2287-2316.; https://doi.org/10.1016/S0967-0637(00)00027-3 nd Pulse-26 cruise nd nd nd 35.667 -121.45 25 nd nd nd nd 0.20 2 North Pacific ash/hydrolysis Loh; A. N.; & Bauer; J. E. (2000). Distribution; partitioning and fluxes of dissolved and particulate organic C; N and P in the eastern North Pacific and Southern Oceans. Deep Sea Research Part I: Oceanographic Research Papers; 47(12); 2287-2316.; https://doi.org/10.1016/S0967-0637(00)00027-3 nd Pulse-26 cruise nd nd nd 35.667 -121.45 100 nd nd nd nd 0.17 2 North Pacific ash/hydrolysis Loh; A. N.; & Bauer; J. E. (2000). Distribution; partitioning and fluxes of dissolved and particulate organic C; N and P in the eastern North Pacific and Southern Oceans. Deep Sea Research Part I: Oceanographic Research Papers; 47(12); 2287-2316.; https://doi.org/10.1016/S0967-0637(00)00027-3 nd Pulse-26 cruise nd nd nd 35.667 -121.45 419 nd nd nd nd 0.01 2 North Pacific ash/hydrolysis Loh; A. N.; & Bauer; J. E. (2000). Distribution; partitioning and fluxes of dissolved and particulate organic C; N and P in the eastern North Pacific and Southern Oceans. Deep Sea Research Part I: Oceanographic Research Papers; 47(12); 2287-2316.; https://doi.org/10.1016/S0967-0637(00)00027-3 nd Pulse-26 cruise nd nd nd 35.667 -121.45 483 nd nd nd nd 0.08 2 North Pacific ash/hydrolysis Loh; A. N.; & Bauer; J. E. (2000). Distribution; partitioning and fluxes of dissolved and particulate organic C; N and P in the eastern North Pacific and Southern Oceans. Deep Sea Research Part I: Oceanographic Research Papers; 47(12); 2287-2316.; https://doi.org/10.1016/S0967-0637(00)00027-3 nd STN F nd nd nd -54 -176 3 nd nd nd nd 0.22 2 Southern Ocean ash/hydrolysis Loh; A. N.; & Bauer; J. E. (2000). Distribution; partitioning and fluxes of dissolved and particulate organic C; N and P in the eastern North Pacific and Southern Oceans. Deep Sea Research Part I: Oceanographic Research Papers; 47(12); 2287-2316.; https://doi.org/10.1016/S0967-0637(00)00027-3 nd STN F nd nd nd -54 -176 10 nd nd nd nd 0.20 2 Southern Ocean ash/hydrolysis Loh; A. N.; & Bauer; J. E. (2000). Distribution; partitioning and fluxes of dissolved and particulate organic C; N and P in the eastern North Pacific and Southern Oceans. Deep Sea Research Part I: Oceanographic Research Papers; 47(12); 2287-2316.; https://doi.org/10.1016/S0967-0637(00)00027-3 nd STN F nd nd nd -54 -176 20 nd nd nd nd 0.23 2 Southern Ocean ash/hydrolysis Loh; A. N.; & Bauer; J. E. (2000). Distribution; partitioning and fluxes of dissolved and particulate organic C; N and P in the eastern North Pacific and Southern Oceans. Deep Sea Research Part I: Oceanographic Research Papers; 47(12); 2287-2316.; https://doi.org/10.1016/S0967-0637(00)00027-3 nd STN F nd nd nd -54 -176 94 nd nd nd nd 0.15 2 Southern Ocean ash/hydrolysis Loh; A. N.; & Bauer; J. E. (2000). Distribution; partitioning and fluxes of dissolved and particulate organic C; N and P in the eastern North Pacific and Southern Oceans. Deep Sea Research Part I: Oceanographic Research Papers; 47(12); 2287-2316.; https://doi.org/10.1016/S0967-0637(00)00027-3 nd STN F nd nd nd -54 -176 142 nd nd nd nd 0.15 2 Southern Ocean ash/hydrolysis Loh; A. N.; & Bauer; J. E. (2000). Distribution; partitioning and fluxes of dissolved and particulate organic C; N and P in the eastern North Pacific and Southern Oceans. Deep Sea Research Part I: Oceanographic Research Papers; 47(12); 2287-2316.; https://doi.org/10.1016/S0967-0637(00)00027-3 nd STN F nd nd nd -54 -176 772 nd nd nd nd 0.10 2 Southern Ocean ash/hydrolysis Loh; A. N.; & Bauer; J. E. (2000). Distribution; partitioning and fluxes of dissolved and particulate organic C; N and P in the eastern North Pacific and Southern Oceans. Deep Sea Research Part I: Oceanographic Research Papers; 47(12); 2287-2316.; https://doi.org/10.1016/S0967-0637(00)00027-3 nd STN F nd nd nd -54 -176 1289 nd nd nd nd 0.07 2 Southern Ocean ash/hydrolysis Loh; A. N.; & Bauer; J. E. (2000). Distribution; partitioning and fluxes of dissolved and particulate organic C; N and P in the eastern North Pacific and Southern Oceans. Deep Sea Research Part I: Oceanographic Research Papers; 47(12); 2287-2316.; https://doi.org/10.1016/S0967-0637(00)00027-3 nd STN F nd nd nd -54 -176 1700 nd nd nd nd 0.06 2 Southern Ocean ash/hydrolysis Loh; A. N.; & Bauer; J. E. (2000). Distribution; partitioning and fluxes of dissolved and particulate organic C; N and P in the eastern North Pacific and Southern Oceans. Deep Sea Research Part I: Oceanographic Research Papers; 47(12); 2287-2316.; https://doi.org/10.1016/S0967-0637(00)00027-3 nd STN F nd nd nd -54 -176 3600 nd nd nd nd 0.07 2 Southern Ocean ash/hydrolysis Loh; A. N.; & Bauer; J. E. (2000). Distribution; partitioning and fluxes of dissolved and particulate organic C; N and P in the eastern North Pacific and Southern Oceans. Deep Sea Research Part I: Oceanographic Research Papers; 47(12); 2287-2316.; https://doi.org/10.1016/S0967-0637(00)00027-3 nd STN F nd nd nd -54 -176 4295 nd nd nd nd 0.08 2 Southern Ocean ash/hydrolysis Loh; A. N.; & Bauer; J. E. (2000). Distribution; partitioning and fluxes of dissolved and particulate organic C; N and P in the eastern North Pacific and Southern Oceans. Deep Sea Research Part I: Oceanographic Research Papers; 47(12); 2287-2316.; https://doi.org/10.1016/S0967-0637(00)00027-3 nd KT00A;B nd nd nd 35 139.333 1 nd nd nd nd 0.37 2 North Pacific ash/hydrolysis Suzumura; M.; & Ingall; E. D. (2004). Distribution and dynamics of various forms of phosphorus in seawater: insights from field observations in the Pacific Ocean and a laboratory experiment. Deep Sea Research Part I: Oceanographic Research Papers; 51(8); 1113-1130.; https://doi.org/10.1016/j.dsr.2004.05.001 nd KT00A;B nd nd nd 35 139.333 9 nd nd nd nd 0.53 2 North Pacific ash/hydrolysis Suzumura; M.; & Ingall; E. D. (2004). Distribution and dynamics of various forms of phosphorus in seawater: insights from field observations in the Pacific Ocean and a laboratory experiment. Deep Sea Research Part I: Oceanographic Research Papers; 51(8); 1113-1130.; https://doi.org/10.1016/j.dsr.2004.05.001 nd KT00A;B nd nd nd 35 139.333 20 nd nd nd nd 0.30 2 North Pacific ash/hydrolysis Suzumura; M.; & Ingall; E. D. (2004). Distribution and dynamics of various forms of phosphorus in seawater: insights from field observations in the Pacific Ocean and a laboratory experiment. Deep Sea Research Part I: Oceanographic Research Papers; 51(8); 1113-1130.; https://doi.org/10.1016/j.dsr.2004.05.001 nd KT00A;B nd nd nd 35 139.333 30 nd nd nd nd 0.36 2 North Pacific ash/hydrolysis Suzumura; M.; & Ingall; E. D. (2004). Distribution and dynamics of various forms of phosphorus in seawater: insights from field observations in the Pacific Ocean and a laboratory experiment. Deep Sea Research Part I: Oceanographic Research Papers; 51(8); 1113-1130.; https://doi.org/10.1016/j.dsr.2004.05.001 nd KT00A;B nd nd nd 35 139.333 50 nd nd nd nd 0.25 2 North Pacific ash/hydrolysis Suzumura; M.; & Ingall; E. D. (2004). Distribution and dynamics of various forms of phosphorus in seawater: insights from field observations in the Pacific Ocean and a laboratory experiment. Deep Sea Research Part I: Oceanographic Research Papers; 51(8); 1113-1130.; https://doi.org/10.1016/j.dsr.2004.05.001 nd KT00A;B nd nd nd 35 139.333 75 nd nd nd nd 0.27 2 North Pacific ash/hydrolysis Suzumura; M.; & Ingall; E. D. (2004). Distribution and dynamics of various forms of phosphorus in seawater: insights from field observations in the Pacific Ocean and a laboratory experiment. Deep Sea Research Part I: Oceanographic Research Papers; 51(8); 1113-1130.; https://doi.org/10.1016/j.dsr.2004.05.001 nd KT00A;B nd nd nd 35 139.333 100 nd nd nd nd 0.20 2 North Pacific ash/hydrolysis Suzumura; M.; & Ingall; E. D. (2004). Distribution and dynamics of various forms of phosphorus in seawater: insights from field observations in the Pacific Ocean and a laboratory experiment. Deep Sea Research Part I: Oceanographic Research Papers; 51(8); 1113-1130.; https://doi.org/10.1016/j.dsr.2004.05.001 nd KT00A;B nd nd nd 35 139.333 151 nd nd nd nd 0.22 2 North Pacific ash/hydrolysis Suzumura; M.; & Ingall; E. D. (2004). Distribution and dynamics of various forms of phosphorus in seawater: insights from field observations in the Pacific Ocean and a laboratory experiment. Deep Sea Research Part I: Oceanographic Research Papers; 51(8); 1113-1130.; https://doi.org/10.1016/j.dsr.2004.05.001 nd KT00A;B nd nd nd 33.107 141.3 2 nd nd nd nd 0.30 2 North Pacific ash/hydrolysis Suzumura; M.; & Ingall; E. D. (2004). Distribution and dynamics of various forms of phosphorus in seawater: insights from field observations in the Pacific Ocean and a laboratory experiment. Deep Sea Research Part I: Oceanographic Research Papers; 51(8); 1113-1130.; https://doi.org/10.1016/j.dsr.2004.05.001 nd KT00A;B nd nd nd 33.107 141.3 10 nd nd nd nd 0.21 2 North Pacific ash/hydrolysis Suzumura; M.; & Ingall; E. D. (2004). Distribution and dynamics of various forms of phosphorus in seawater: insights from field observations in the Pacific Ocean and a laboratory experiment. Deep Sea Research Part I: Oceanographic Research Papers; 51(8); 1113-1130.; https://doi.org/10.1016/j.dsr.2004.05.001 nd KT00A;B nd nd nd 33.107 141.3 20 nd nd nd nd 0.43 2 North Pacific ash/hydrolysis Suzumura; M.; & Ingall; E. D. (2004). Distribution and dynamics of various forms of phosphorus in seawater: insights from field observations in the Pacific Ocean and a laboratory experiment. Deep Sea Research Part I: Oceanographic Research Papers; 51(8); 1113-1130.; https://doi.org/10.1016/j.dsr.2004.05.001 nd KT00A;B nd nd nd 33.107 141.3 30 nd nd nd nd 0.35 2 North Pacific ash/hydrolysis Suzumura; M.; & Ingall; E. D. (2004). Distribution and dynamics of various forms of phosphorus in seawater: insights from field observations in the Pacific Ocean and a laboratory experiment. Deep Sea Research Part I: Oceanographic Research Papers; 51(8); 1113-1130.; https://doi.org/10.1016/j.dsr.2004.05.001 nd KT00A;B nd nd nd 33.107 141.3 50 nd nd nd nd 0.43 2 North Pacific ash/hydrolysis Suzumura; M.; & Ingall; E. D. (2004). Distribution and dynamics of various forms of phosphorus in seawater: insights from field observations in the Pacific Ocean and a laboratory experiment. Deep Sea Research Part I: Oceanographic Research Papers; 51(8); 1113-1130.; https://doi.org/10.1016/j.dsr.2004.05.001 nd KT00A;B nd nd nd 33.107 141.3 75 nd nd nd nd 0.22 2 North Pacific ash/hydrolysis Suzumura; M.; & Ingall; E. D. (2004). Distribution and dynamics of various forms of phosphorus in seawater: insights from field observations in the Pacific Ocean and a laboratory experiment. Deep Sea Research Part I: Oceanographic Research Papers; 51(8); 1113-1130.; https://doi.org/10.1016/j.dsr.2004.05.001 nd KT00A;B nd nd nd 33.107 141.3 100 nd nd nd nd 0.25 2 North Pacific ash/hydrolysis Suzumura; M.; & Ingall; E. D. (2004). Distribution and dynamics of various forms of phosphorus in seawater: insights from field observations in the Pacific Ocean and a laboratory experiment. Deep Sea Research Part I: Oceanographic Research Papers; 51(8); 1113-1130.; https://doi.org/10.1016/j.dsr.2004.05.001 nd KT00A;B nd nd nd 33.107 141.3 150 nd nd nd nd 0.23 2 North Pacific ash/hydrolysis Suzumura; M.; & Ingall; E. D. (2004). Distribution and dynamics of various forms of phosphorus in seawater: insights from field observations in the Pacific Ocean and a laboratory experiment. Deep Sea Research Part I: Oceanographic Research Papers; 51(8); 1113-1130.; https://doi.org/10.1016/j.dsr.2004.05.001 nd KT00A;B nd nd nd 33.107 141.3 2001 nd nd nd nd 0.05 2 North Pacific ash/hydrolysis Suzumura; M.; & Ingall; E. D. (2004). Distribution and dynamics of various forms of phosphorus in seawater: insights from field observations in the Pacific Ocean and a laboratory experiment. Deep Sea Research Part I: Oceanographic Research Papers; 51(8); 1113-1130.; https://doi.org/10.1016/j.dsr.2004.05.001 nd KT00A;B nd nd nd 33.107 141.3 3000 nd nd nd nd 0.04 2 North Pacific ash/hydrolysis Suzumura; M.; & Ingall; E. D. (2004). Distribution and dynamics of various forms of phosphorus in seawater: insights from field observations in the Pacific Ocean and a laboratory experiment. Deep Sea Research Part I: Oceanographic Research Papers; 51(8); 1113-1130.; https://doi.org/10.1016/j.dsr.2004.05.001 nd KH01Eq nd nd nd 0 159.998 10 nd nd nd nd 0.21 2 North Pacific ash/hydrolysis Suzumura; M.; & Ingall; E. D. (2004). Distribution and dynamics of various forms of phosphorus in seawater: insights from field observations in the Pacific Ocean and a laboratory experiment. Deep Sea Research Part I: Oceanographic Research Papers; 51(8); 1113-1130.; https://doi.org/10.1016/j.dsr.2004.05.001 nd KH01Eq nd nd nd 0 159.998 51 nd nd nd nd 0.34 2 North Pacific ash/hydrolysis Suzumura; M.; & Ingall; E. D. (2004). Distribution and dynamics of various forms of phosphorus in seawater: insights from field observations in the Pacific Ocean and a laboratory experiment. Deep Sea Research Part I: Oceanographic Research Papers; 51(8); 1113-1130.; https://doi.org/10.1016/j.dsr.2004.05.001 nd KH01Eq nd nd nd 0 159.998 101 nd nd nd nd 0.38 2 North Pacific ash/hydrolysis Suzumura; M.; & Ingall; E. D. (2004). Distribution and dynamics of various forms of phosphorus in seawater: insights from field observations in the Pacific Ocean and a laboratory experiment. Deep Sea Research Part I: Oceanographic Research Papers; 51(8); 1113-1130.; https://doi.org/10.1016/j.dsr.2004.05.001 nd KH01Eq nd nd nd 0 159.998 996 nd nd nd nd 0.08 2 North Pacific ash/hydrolysis Suzumura; M.; & Ingall; E. D. (2004). Distribution and dynamics of various forms of phosphorus in seawater: insights from field observations in the Pacific Ocean and a laboratory experiment. Deep Sea Research Part I: Oceanographic Research Papers; 51(8); 1113-1130.; https://doi.org/10.1016/j.dsr.2004.05.001 nd KH01Eq nd nd nd 0 159.998 1979 nd nd nd nd 0.06 2 North Pacific ash/hydrolysis Suzumura; M.; & Ingall; E. D. (2004). Distribution and dynamics of various forms of phosphorus in seawater: insights from field observations in the Pacific Ocean and a laboratory experiment. Deep Sea Research Part I: Oceanographic Research Papers; 51(8); 1113-1130.; https://doi.org/10.1016/j.dsr.2004.05.001 nd KH01Eq nd nd nd 0 159.998 3941 nd nd nd nd 0.05 2 North Pacific ash/hydrolysis Suzumura; M.; & Ingall; E. D. (2004). Distribution and dynamics of various forms of phosphorus in seawater: insights from field observations in the Pacific Ocean and a laboratory experiment. Deep Sea Research Part I: Oceanographic Research Papers; 51(8); 1113-1130.; https://doi.org/10.1016/j.dsr.2004.05.001 nd OC279 nd nd nd 32.18 -70.11 1 23.02 nd 0.00 0.00 0.15 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 32.18 -70.11 15 22.56 nd 0.00 0.00 0.12 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 32.18 -70.11 25 21.98 nd 0.01 0.00 0.11 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 32.18 -70.11 40 20.55 nd 0.01 0.01 0.09 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 32.18 -70.11 60 19.3 nd 0.00 0.00 0.09 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 32.18 -70.11 75 19.08 nd 0.01 0.00 0.09 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 32.18 -70.11 100 18.83 nd 0.90 0.02 0.13 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 32.18 -70.11 120 18.69 nd 1.55 0.03 0.14 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 35 -69.88 1 23.5 nd 0.01 0.38 0.11 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 35 -69.88 20 22.3 nd 0.00 0.01 0.09 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 35 -69.88 40 20.7 nd 0.01 0.01 0.10 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 35 -69.88 60 19.15 nd 0.01 0.01 0.11 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 35 -69.88 100 18.66 nd 0.76 0.01 0.11 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 35 -69.88 140 18.47 nd 2.10 0.06 0.11 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 35 -69.88 160 18.43 nd 0.82 0.02 0.10 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 35 -69.88 180 18.35 nd 1.05 0.02 0.05 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 36.2 -69.54 1 24.98 nd 0.00 0.00 0.11 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 36.2 -69.54 20 24.43 nd 0.02 0.00 0.11 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 36.2 -69.54 40 22.83 nd 0.00 0.01 0.10 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 36.2 -69.54 60 22.02 nd 0.01 0.01 0.10 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 36.2 -69.54 80 21.57 nd 0.01 0.01 0.07 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 36.2 -69.54 90 21.47 nd nd 0.00 0.09 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 36.2 -69.54 100 20.42 nd 0.02 0.01 0.09 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 36.2 -69.54 120 19.93 nd 0.01 0.01 0.09 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 36.2 -69.54 140 19.58 nd 2.55 0.07 0.06 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 36.2 -69.54 160 nd nd 0.42 0.04 0.04 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 37.5 -69.92 1 26.8 nd 0.00 0.00 0.10 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 37.5 -69.92 30 26.8 nd 0.00 0.00 0.10 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 37.5 -69.92 50 26.29 nd 0.00 0.00 0.06 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 37.5 -69.92 60 25.97 nd 0.00 0.00 0.07 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 37.5 -69.92 80 24.48 nd 0.08 0.01 0.11 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 37.5 -69.92 100 23.99 nd 0.49 0.01 0.11 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 37.5 -69.92 120 23.14 nd 0.08 0.00 0.05 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 37.5 -69.92 140 22.15 nd 0.12 0.06 0.07 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 37.5 -69.92 180 20.56 nd 1.21 nd 0.04 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 37.5 -69.92 220 18.07 nd 7.70 0.12 0.12 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 38.62 -70.62 1 20.91 nd 0.00 0.08 0.07 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 38.62 -70.62 20 19.44 nd 0.00 0.11 0.08 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 38.62 -70.62 40 16.1 nd 4.43 0.21 0.07 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 38.62 -70.62 60 13.73 nd 7.38 0.27 0.08 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 39.5 -70.72 1 20.33 nd 0.02 0.19 0.11 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 39.5 -70.72 10 13.26 nd 0.01 0.18 0.07 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 39.5 -70.72 20 14.05 nd 0.01 0.24 0.18 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 39.5 -70.72 36 11.05 nd 2.74 0.46 0.08 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 40 -70.72 1 19.22 nd 0.01 0.22 0.11 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC279 nd nd nd 40 -70.72 20 15.44 nd 0.00 0.14 0.16 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC297 nd nd nd 35.83 -61.95 3 19.22 nd 0.84 0.02 0.10 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC297 nd nd nd 35.83 -61.95 25 19.22 nd 0.88 0.02 0.04 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC297 nd nd nd 35.83 -61.95 50 19.19 nd 0.77 0.02 0.09 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC297 nd nd nd 35.83 -61.95 125 19.17 nd 0.74 0.02 0.05 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC297 nd nd nd 35.83 -61.95 150 19.17 nd 0.73 0.02 0.07 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC297 nd nd nd 35.83 -61.95 175 19.17 nd 0.74 0.02 0.08 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC297 nd nd nd 35.83 -61.95 200 19.15 nd 0.77 0.02 0.08 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC297 nd nd nd 35.83 -61.95 250 18.74 nd 1.95 0.07 0.04 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC297 nd nd nd 36.5 -65.83 3 19.3 nd 0.53 0.00 0.12 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC297 nd nd nd 36.5 -65.83 40 19.22 nd 0.65 0.00 0.05 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC297 nd nd nd 36.5 -65.83 75 19.22 nd 0.68 0.00 0.14 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC297 nd nd nd 36.5 -65.83 100 19.23 nd 0.63 0.00 0.10 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC297 nd nd nd 36.5 -65.83 150 19.21 nd 0.76 0.01 0.09 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC297 nd nd nd 36.5 -65.83 200 19.1 nd 0.96 0.08 0.05 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC297 nd nd nd 36.5 -65.83 250 18.58 nd 2.32 0.08 0.09 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC297 nd nd nd 36.5 -65.83 300 18.26 nd 2.43 0.08 0.04 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC297 nd nd nd 38.08 -67.66 3 23.35 nd 3.04 0.03 0.03 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC297 nd nd nd 38.08 -67.66 30 23.45 nd 0.30 0.00 0.06 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC297 nd nd nd 38.08 -67.66 50 23.41 nd 2.01 0.03 0.05 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC297 nd nd nd 38.08 -67.66 70 22.64 nd 2.62 0.07 0.11 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC297 nd nd nd 38.08 -67.66 100 20.53 nd 0.64 0.00 0.06 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC297 nd nd nd 38.08 -67.66 150 19.79 nd 0.95 0.11 0.10 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC297 nd nd nd 38.08 -67.66 200 18.63 nd 2.63 0.09 0.09 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 26.281 -69.812 3 24.9 nd 0.01 0.00 0.09 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 26.685 -69.411 3 24.3 nd 0.00 0.00 0.18 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 27.668 -68.428 3 23.5 nd 0.00 0.00 0.09 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 27.793 -68.305 3 23.3 nd 0.00 0.00 0.12 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 28.001 -68.097 3 22.1 nd 0.01 0.00 0.06 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 28.49 -67.66 3 22.3 nd 0.01 0.00 0.11 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 28.693 -67.469 3 21.5 nd 0.00 0.00 0.11 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 28.913 -67.247 3 22.1 nd 0.00 0.00 0.10 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 29.975 -66.104 3 21.2 nd 0.00 0.00 0.12 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 30.312 -65.667 3 21.6 nd 0.00 nd 0.10 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 30.565 -65.431 3 21.7 nd 0.00 0.00 0.10 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 30.69 -65.286 3 21.1 nd 0.02 0.00 0.13 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 30.928 -65.016 3 19.7 nd 0.15 0.00 0.08 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 31.079 -64.843 3 19.6 nd 0.11 0.00 0.07 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 31.257 -64.639 3 19.5 nd 0.22 0.00 0.07 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 31.437 -64.431 3 19.4 nd 0.16 0.00 0.08 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 31.867 -64.637 3 19.4 nd 0.58 0.01 0.08 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 32.093 -65.091 3 19.4 nd 0.32 0.01 0.09 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 32.506 -65.806 3 19.1 nd 0.60 0.01 0.09 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 32.588 -65.942 3 19.2 nd 0.54 nd 0.08 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 32.713 -66.155 3 19.2 nd 0.66 nd 0.13 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 33.396 -67.294 3 20 nd 0.42 0.01 0.09 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 33.933 -68.21 3 19.4 nd 0.81 0.02 0.10 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 33.999 -68.318 3 19.3 nd 0.66 0.01 0.12 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 34.408 -69 3 19.3 nd 0.71 0.01 0.08 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 34.579 -69.211 3 19.4 nd 0.61 0.01 0.14 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 34.696 -69.356 3 19.4 nd 0.67 0.01 0.13 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 34.894 -69.596 3 19.4 nd 0.71 0.01 0.11 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 35.638 -70.16 3 19.5 nd 0.47 0.01 0.10 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 36.846 -70.755 3 23.8 nd 0.17 0.01 0.10 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 37.007 -70.741 3 23.4 nd 0.37 0.01 0.08 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 37.263 -70.73 3 23.4 nd 0.37 0.02 0.11 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 37.406 -70.728 3 23.1 nd 0.59 0.02 0.12 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 37.592 -70.725 3 21 nd 0.90 0.04 0.11 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 37.694 -70.724 3 19.2 nd 1.48 0.08 0.12 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 37.759 -70.722 3 9.51 nd 3.10 0.34 0.09 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 37.843 -70.722 3 10.9 nd 3.17 0.27 0.09 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 37.987 -70.729 3 10.6 nd 2.69 0.31 0.08 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 39.434 -70.798 3 4.9 nd 4.09 0.43 0.09 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 39.519 -70.802 3 4.66 nd 2.64 0.51 0.14 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 39.729 -70.812 3 4.9 nd 2.63 0.48 0.16 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 39.813 -70.816 3 4.4 nd 3.32 0.26 0.19 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 39.902 -70.821 3 4.4 nd 4.61 0.48 0.15 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 40.103 -70.819 3 4.83 nd 4.39 0.58 0.10 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 40.212 -70.825 3 5.1 nd 5.01 0.36 0.11 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 26 -70.009 0 nd nd 0.00 0.00 0.10 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 26 -70.009 50 nd nd 0.00 0.00 0.10 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 26 -70.009 80 nd nd 0.00 0.00 0.08 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 31.567 -64.147 0 nd nd 0.20 0.00 0.05 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 31.567 -64.147 100 nd nd 0.26 0.00 0.10 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 31.567 -64.147 150 nd nd 0.26 0.00 0.08 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC318 nd nd nd 31.567 -64.147 200 nd nd 0.94 0.03 0.13 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC325 nd nd nd 31.665556 -64.158333 20 nd nd 0.01 0.00 0.09 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC325 nd nd nd 31.665556 -64.158333 50 nd nd 0.00 0.00 0.13 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC325 nd nd nd 31.665556 -64.158333 80 nd nd 0.23 0.01 0.17 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC325 nd nd nd 31.665556 -64.158333 100 nd nd 1.14 0.02 0.10 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC325 nd nd nd 31.665556 -64.158333 125 nd nd 1.58 0.04 0.07 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC325 nd nd nd 31.665556 -64.158333 150 nd nd 1.64 0.05 0.13 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC325 nd nd nd 31.665556 -64.158333 200 nd nd 3.49 0.11 0.08 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC325 nd nd nd 31.664444 -64.165278 400 nd nd 5.22 0.18 0.06 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC325 nd nd nd 31.664444 -64.165278 3 nd nd 0.01 0.00 0.06 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC325 nd nd nd 31.664444 -64.165278 15 nd nd 0.01 0.00 0.08 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC325 nd nd nd 31.664444 -64.165278 20 nd nd 0.00 0.00 0.08 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC325 nd nd nd 31.664444 -64.165278 30 nd nd 0.00 0.00 0.14 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC325 nd nd nd 31.664444 -64.165278 50 nd nd 0.00 0.00 0.10 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC325 nd nd nd 31.664444 -64.165278 75 nd nd 0.75 0.02 0.09 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC325 nd nd nd 31.664444 -64.165278 100 nd nd 1.14 0.04 0.14 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC325 nd nd nd 31.664444 -64.165278 125 nd nd 1.69 0.03 0.08 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC325 nd nd nd 31.664444 -64.165278 150 nd nd 1.53 0.04 0.08 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC325 nd nd nd 31.664444 -64.165278 200 nd nd 4.27 0.09 0.12 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC325 nd nd nd 31.657222 -64.126111 400 nd nd 1.59 0.04 0.06 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC325 nd nd nd 31.657222 -64.126111 3 nd nd 0.01 0.10 0.18 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC325 nd nd nd 31.657222 -64.126111 15 nd nd 0.01 0.06 0.08 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC325 nd nd nd 31.657222 -64.126111 20 nd nd 0.01 0.07 0.11 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC325 nd nd nd 31.657222 -64.126111 30 nd nd 0.01 0.09 0.01 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC325 nd nd nd 31.657222 -64.126111 50 nd nd 1.33 0.21 0.01 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC325 nd nd nd 31.657222 -64.126111 80 nd nd 6.45 0.36 0.02 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC325 nd nd nd 31.653889 -64.121944 0 nd nd 0.01 0.10 0.03 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC325 nd nd nd 31.653889 -64.121944 5 nd nd 0.01 0.10 0.11 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC325 nd nd nd 31.653889 -64.121944 10 nd nd 0.01 0.22 0.08 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd OC325 nd nd nd 31.653889 -64.121944 30 nd nd 1.12 0.31 0.14 2 North Atlantic UV oxidation Cavender-Bares; K. K.; Karl; D. M.; & Chisholm; S. W. (2001). Nutrient gradients in the western North Atlantic Ocean: Relationship to microbial community structure and comparison to patterns in the Pacific Ocean. Deep Sea Research Part I: Oceanographic Research Papers; 48(11); 2373-2395. nd Station ALOHA nd nd nd 22.75 -158 5 nd nd 0.00 0.06 0.20 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 49 nd nd 0.00 0.06 0.20 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 74 nd nd 0.00 0.04 0.20 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 107 nd nd 0.00 0.06 0.17 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 180 nd nd 1.29 0.16 0.13 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 197 nd nd 2.33 0.25 0.12 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 250 nd nd 4.65 0.39 0.10 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 261 nd nd 6.02 0.48 0.10 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 325 nd nd 13.44 0.98 0.08 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 419 nd nd 20.19 1.45 0.08 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 450 nd nd 27.33 1.99 0.07 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 500 nd nd nd 2.36 0.06 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 505 nd nd 32.20 2.33 0.07 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 516 nd nd 32.76 2.38 0.07 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 577 nd nd 36.42 2.68 0.07 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 637 nd nd 39.40 2.89 0.06 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 737 nd nd 41.92 3.10 0.05 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 850 nd nd 42.30 3.12 0.05 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 994 nd nd 42.70 3.12 0.05 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 1200 nd nd 42.89 3.09 0.05 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 1400 nd nd 42.42 3.07 0.05 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 1600 nd nd 42.05 3.01 0.05 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 2000 nd nd 40.94 2.91 0.05 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 2200 nd nd 40.47 2.86 0.05 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 2400 nd nd 40.11 2.81 0.06 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 2600 nd nd 40.40 2.87 0.05 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 2800 nd nd 39.39 2.73 0.05 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 3000 nd nd 38.70 2.71 0.05 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 3200 nd nd 38.31 2.67 0.05 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 3400 nd nd 37.61 2.63 0.05 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 3600 nd nd 37.67 2.60 0.05 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 4000 nd nd 37.06 2.59 0.04 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 4200 nd nd 36.85 2.56 0.05 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 4400 nd nd 36.89 2.55 0.05 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 4500 nd nd 36.77 2.56 0.05 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 4600 nd nd 36.90 2.54 0.05 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station ALOHA nd nd nd 22.75 -158 4800 nd nd 36.45 2.55 0.05 2 South Pacific UV oxidation Foreman; R.K.; Bj rkman; K.M.; Carlson; C.A.; Opalk; K. and Karl; D.M. (2019); Improved ultraviolet photo-oxidation system yields estimates for deep-sea dissolved organic nitrogen and phosphorus. Limnol Oceanogr Methods; 17: 277-291. https://doi.org/10.1002/lom3.10312 nd Station BATS nd nd nd 31.7 -64.2 5 nd nd nd nd 0.06 2 North Atlantic Wet oxidation Lomas; M. W.; Burke; A. L.; Lomas; D. A.; Bell; D. W.; Shen; C.; Dyhrman; S. T.; and Ammerman; J. W.: Sargasso Sea phosphorus biogeochemistry: an important role for dissolved organic phosphorus (DOP); Biogeosciences; 7; 695 710; https://doi.org/10.5194/bg-7-695-2010; 2010. nd Station BATS nd nd nd 31.7 -64.2 15 nd nd nd nd 0.06 2 North Atlantic Wet oxidation Lomas; M. W.; Burke; A. L.; Lomas; D. A.; Bell; D. W.; Shen; C.; Dyhrman; S. T.; and Ammerman; J. W.: Sargasso Sea phosphorus biogeochemistry: an important role for dissolved organic phosphorus (DOP); Biogeosciences; 7; 695 710; https://doi.org/10.5194/bg-7-695-2010; 2010. nd Station BATS nd nd nd 31.7 -64.2 25 nd nd nd nd 0.06 2 North Atlantic Wet oxidation Lomas; M. W.; Burke; A. L.; Lomas; D. A.; Bell; D. W.; Shen; C.; Dyhrman; S. T.; and Ammerman; J. W.: Sargasso Sea phosphorus biogeochemistry: an important role for dissolved organic phosphorus (DOP); Biogeosciences; 7; 695 710; https://doi.org/10.5194/bg-7-695-2010; 2010. nd Station BATS nd nd nd 31.7 -64.2 45 nd nd nd nd 0.06 2 North Atlantic Wet oxidation Lomas; M. W.; Burke; A. L.; Lomas; D. A.; Bell; D. W.; Shen; C.; Dyhrman; S. T.; and Ammerman; J. W.: Sargasso Sea phosphorus biogeochemistry: an important role for dissolved organic phosphorus (DOP); Biogeosciences; 7; 695 710; https://doi.org/10.5194/bg-7-695-2010; 2010. nd Station BATS nd nd nd 31.7 -64.2 65 nd nd nd nd 0.06 2 North Atlantic Wet oxidation Lomas; M. W.; Burke; A. L.; Lomas; D. A.; Bell; D. W.; Shen; C.; Dyhrman; S. T.; and Ammerman; J. W.: Sargasso Sea phosphorus biogeochemistry: an important role for dissolved organic phosphorus (DOP); Biogeosciences; 7; 695 710; https://doi.org/10.5194/bg-7-695-2010; 2010. nd Station BATS nd nd nd 31.7 -64.2 85 nd nd nd nd 0.06 2 North Atlantic Wet oxidation Lomas; M. W.; Burke; A. L.; Lomas; D. A.; Bell; D. W.; Shen; C.; Dyhrman; S. T.; and Ammerman; J. W.: Sargasso Sea phosphorus biogeochemistry: an important role for dissolved organic phosphorus (DOP); Biogeosciences; 7; 695 710; https://doi.org/10.5194/bg-7-695-2010; 2010. nd Station BATS nd nd nd 31.7 -64.2 105 nd nd nd nd 0.07 2 North Atlantic Wet oxidation Lomas; M. W.; Burke; A. L.; Lomas; D. A.; Bell; D. W.; Shen; C.; Dyhrman; S. T.; and Ammerman; J. W.: Sargasso Sea phosphorus biogeochemistry: an important role for dissolved organic phosphorus (DOP); Biogeosciences; 7; 695 710; https://doi.org/10.5194/bg-7-695-2010; 2010. nd Station BATS nd nd nd 31.7 -64.2 125 nd nd nd nd 0.07 2 North Atlantic Wet oxidation Lomas; M. W.; Burke; A. L.; Lomas; D. A.; Bell; D. W.; Shen; C.; Dyhrman; S. T.; and Ammerman; J. W.: Sargasso Sea phosphorus biogeochemistry: an important role for dissolved organic phosphorus (DOP); Biogeosciences; 7; 695 710; https://doi.org/10.5194/bg-7-695-2010; 2010. nd Station BATS nd nd nd 31.7 -64.2 145 nd nd nd nd 0.07 2 North Atlantic Wet oxidation Lomas; M. W.; Burke; A. L.; Lomas; D. A.; Bell; D. W.; Shen; C.; Dyhrman; S. T.; and Ammerman; J. W.: Sargasso Sea phosphorus biogeochemistry: an important role for dissolved organic phosphorus (DOP); Biogeosciences; 7; 695 710; https://doi.org/10.5194/bg-7-695-2010; 2010. nd Station BATS nd nd nd 31.7 -64.2 165 nd nd nd nd 0.07 2 North Atlantic Wet oxidation Lomas; M. W.; Burke; A. L.; Lomas; D. A.; Bell; D. W.; Shen; C.; Dyhrman; S. T.; and Ammerman; J. W.: Sargasso Sea phosphorus biogeochemistry: an important role for dissolved organic phosphorus (DOP); Biogeosciences; 7; 695 710; https://doi.org/10.5194/bg-7-695-2010; 2010. nd Station BATS nd nd nd 31.7 -64.2 205 nd nd nd nd 0.07 2 North Atlantic Wet oxidation Lomas; M. W.; Burke; A. L.; Lomas; D. A.; Bell; D. W.; Shen; C.; Dyhrman; S. T.; and Ammerman; J. W.: Sargasso Sea phosphorus biogeochemistry: an important role for dissolved organic phosphorus (DOP); Biogeosciences; 7; 695 710; https://doi.org/10.5194/bg-7-695-2010; 2010. nd Station BATS nd nd nd 31.7 -64.2 225 nd nd nd nd 0.07 2 North Atlantic Wet oxidation Lomas; M. W.; Burke; A. L.; Lomas; D. A.; Bell; D. W.; Shen; C.; Dyhrman; S. T.; and Ammerman; J. W.: Sargasso Sea phosphorus biogeochemistry: an important role for dissolved organic phosphorus (DOP); Biogeosciences; 7; 695 710; https://doi.org/10.5194/bg-7-695-2010; 2010. nd Station BATS nd nd nd 31.7 -64.2 255 nd nd nd nd 0.05 2 North Atlantic Wet oxidation Lomas; M. W.; Burke; A. L.; Lomas; D. A.; Bell; D. W.; Shen; C.; Dyhrman; S. T.; and Ammerman; J. W.: Sargasso Sea phosphorus biogeochemistry: an important role for dissolved organic phosphorus (DOP); Biogeosciences; 7; 695 710; https://doi.org/10.5194/bg-7-695-2010; 2010. nd Station BATS nd nd nd 31.7 -64.2 405 nd nd nd nd 0.04 2 North Atlantic Wet oxidation Lomas; M. W.; Burke; A. L.; Lomas; D. A.; Bell; D. W.; Shen; C.; Dyhrman; S. T.; and Ammerman; J. W.: Sargasso Sea phosphorus biogeochemistry: an important role for dissolved organic phosphorus (DOP); Biogeosciences; 7; 695 710; https://doi.org/10.5194/bg-7-695-2010; 2010. nd Station BATS nd nd nd 31.7 -64.2 505 nd nd nd nd 0.02 2 North Atlantic Wet oxidation Lomas; M. W.; Burke; A. L.; Lomas; D. A.; Bell; D. W.; Shen; C.; Dyhrman; S. T.; and Ammerman; J. W.: Sargasso Sea phosphorus biogeochemistry: an important role for dissolved organic phosphorus (DOP); Biogeosciences; 7; 695 710; https://doi.org/10.5194/bg-7-695-2010; 2010. nd EN391 2004-03-13 2 nd 31.82655 -64.1776 0 nd nd nd 0.05 0.17 2 North Atlantic ash/hydrolysis Sohm; J. A.; & Capone; D. G. (2006). Phosphorus dynamics of the tropical and subtropical north Atlantic: Trichodesmium spp. versus bulk plankton. Marine Ecology Progress Series; 317; 21-28. doi:10.3354/meps317021 nd EN391 2004-03-14 A nd 29.2796666666667 -61.541666666667 0 nd nd nd 0.01 0.18 2 North Atlantic ash/hydrolysis Sohm; J. A.; & Capone; D. G. (2006). Phosphorus dynamics of the tropical and subtropical north Atlantic: Trichodesmium spp. versus bulk plankton. Marine Ecology Progress Series; 317; 21-28. doi:10.3354/meps317021 nd EN391 2004-03-14 B nd 28.0576666666667 -60.335666666667 0 nd nd nd 0.02 0.09 2 North Atlantic ash/hydrolysis Sohm; J. A.; & Capone; D. G. (2006). Phosphorus dynamics of the tropical and subtropical north Atlantic: Trichodesmium spp. versus bulk plankton. Marine Ecology Progress Series; 317; 21-28. doi:10.3354/meps317021 nd EN391 2004-03-16 C nd 23.7066666666667 -56.131666666667 0 nd nd nd 0.01 0.06 2 North Atlantic ash/hydrolysis Sohm; J. A.; & Capone; D. G. (2006). Phosphorus dynamics of the tropical and subtropical north Atlantic: Trichodesmium spp. versus bulk plankton. Marine Ecology Progress Series; 317; 21-28. doi:10.3354/meps317021 nd EN391 2004-03-16 D nd 22.3216666666667 -54.881666666667 0 nd nd nd 0.01 0.06 2 North Atlantic ash/hydrolysis Sohm; J. A.; & Capone; D. G. (2006). Phosphorus dynamics of the tropical and subtropical north Atlantic: Trichodesmium spp. versus bulk plankton. Marine Ecology Progress Series; 317; 21-28. doi:10.3354/meps317021 nd EN391 2004-03-18 E nd 17.12 -52.193333333333 0 nd nd nd 0.04 0.10 2 North Atlantic ash/hydrolysis Sohm; J. A.; & Capone; D. G. (2006). Phosphorus dynamics of the tropical and subtropical north Atlantic: Trichodesmium spp. versus bulk plankton. Marine Ecology Progress Series; 317; 21-28. doi:10.3354/meps317021 nd EN391 2004-03-18 F nd 15.8866666666667 -51.325 0 nd nd nd 0.03 0.12 2 North Atlantic ash/hydrolysis Sohm; J. A.; & Capone; D. G. (2006). Phosphorus dynamics of the tropical and subtropical north Atlantic: Trichodesmium spp. versus bulk plankton. Marine Ecology Progress Series; 317; 21-28. doi:10.3354/meps317021 nd SJ0609 2006-06-28 3 nd 12.3 -56.1 0 nd 31.7 nd 0.02 0.16 2 North Atlantic ash/hydrolysis Sohm; J. A.; and Capone; D. G. (2010); Zonal differences in phosphorus pools; turnover and deficiency across the tropical North Atlantic Ocean; Global Biogeochem. Cycles; 24; GB2008; doi:10.1029/2008GB003414. nd SJ0609 2006-06-28 4 nd 12 -54.5 0 nd 30.1 nd 0.03 0.10 2 North Atlantic ash/hydrolysis Sohm; J. A.; and Capone; D. G. (2010); Zonal differences in phosphorus pools; turnover and deficiency across the tropical North Atlantic Ocean; Global Biogeochem. Cycles; 24; GB2008; doi:10.1029/2008GB003414. nd SJ0609 2006-06-28 5 nd 11.7 -51.5 0 nd 33.8 nd 0.02 0.25 2 North Atlantic ash/hydrolysis Sohm; J. A.; and Capone; D. G. (2010); Zonal differences in phosphorus pools; turnover and deficiency across the tropical North Atlantic Ocean; Global Biogeochem. Cycles; 24; GB2008; doi:10.1029/2008GB003414. nd SJ0609 2006-06-30 6 nd 11.7 -49.5 0 nd 35.9 nd 0.01 0.23 2 North Atlantic ash/hydrolysis Sohm; J. A.; and Capone; D. G. (2010); Zonal differences in phosphorus pools; turnover and deficiency across the tropical North Atlantic Ocean; Global Biogeochem. Cycles; 24; GB2008; doi:10.1029/2008GB003414. nd SJ0609 2006-07-01 7 nd 11.8 -46.2 0 nd 36.4 nd 0.02 0.24 2 North Atlantic ash/hydrolysis Sohm; J. A.; and Capone; D. G. (2010); Zonal differences in phosphorus pools; turnover and deficiency across the tropical North Atlantic Ocean; Global Biogeochem. Cycles; 24; GB2008; doi:10.1029/2008GB003414. nd SJ0609 2006-07-03 8 nd 11.8 -43.4 0 nd 36.1 nd 0.02 0.22 2 North Atlantic ash/hydrolysis Sohm; J. A.; and Capone; D. G. (2010); Zonal differences in phosphorus pools; turnover and deficiency across the tropical North Atlantic Ocean; Global Biogeochem. Cycles; 24; GB2008; doi:10.1029/2008GB003414. nd SJ0609 2006-07-04 9 nd 12.5 -40.1 0 nd 36.4 nd nd 0.23 2 North Atlantic ash/hydrolysis Sohm; J. A.; and Capone; D. G. (2010); Zonal differences in phosphorus pools; turnover and deficiency across the tropical North Atlantic Ocean; Global Biogeochem. Cycles; 24; GB2008; doi:10.1029/2008GB003414. nd SJ0609 2006-07-06 10 nd 13.9 -35.3 0 nd 36.4 nd nd 0.20 2 North Atlantic ash/hydrolysis Sohm; J. A.; and Capone; D. G. (2010); Zonal differences in phosphorus pools; turnover and deficiency across the tropical North Atlantic Ocean; Global Biogeochem. Cycles; 24; GB2008; doi:10.1029/2008GB003414. nd SJ0609 2006-07-07 12 nd 15 -32 0 nd 36.3 nd 0.01 0.12 2 North Atlantic ash/hydrolysis Sohm; J. A.; and Capone; D. G. (2010); Zonal differences in phosphorus pools; turnover and deficiency across the tropical North Atlantic Ocean; Global Biogeochem. Cycles; 24; GB2008; doi:10.1029/2008GB003414. nd SJ0609 2006-07-12 13 nd 12.4 -27.2 0 nd 36.2 nd 0.01 0.18 2 North Atlantic ash/hydrolysis Sohm; J. A.; and Capone; D. G. (2010); Zonal differences in phosphorus pools; turnover and deficiency across the tropical North Atlantic Ocean; Global Biogeochem. Cycles; 24; GB2008; doi:10.1029/2008GB003414. nd SJ0609 2006-07-13 14 nd 10 -28.8 0 nd 35.9 nd 0.03 0.21 2 North Atlantic ash/hydrolysis Sohm; J. A.; and Capone; D. G. (2010); Zonal differences in phosphorus pools; turnover and deficiency across the tropical North Atlantic Ocean; Global Biogeochem. Cycles; 24; GB2008; doi:10.1029/2008GB003414. nd SJ0609 2006-07-14 15 nd 6.6 -30.8 0 nd 35.1 nd 0.01 0.11 2 North Atlantic ash/hydrolysis Sohm; J. A.; and Capone; D. G. (2010); Zonal differences in phosphorus pools; turnover and deficiency across the tropical North Atlantic Ocean; Global Biogeochem. Cycles; 24; GB2008; doi:10.1029/2008GB003414. nd SJ0609 2006-07-18 18 nd 1.8 -38.5 0 nd 35.6 nd 0.02 0.19 2 North Atlantic ash/hydrolysis Sohm; J. A.; and Capone; D. G. (2010); Zonal differences in phosphorus pools; turnover and deficiency across the tropical North Atlantic Ocean; Global Biogeochem. Cycles; 24; GB2008; doi:10.1029/2008GB003414. nd SJ0609 2006-07-19 19 nd 3.6 -41.9 0 nd 35.4 nd 0.03 0.15 2 North Atlantic ash/hydrolysis Sohm; J. A.; and Capone; D. G. (2010); Zonal differences in phosphorus pools; turnover and deficiency across the tropical North Atlantic Ocean; Global Biogeochem. Cycles; 24; GB2008; doi:10.1029/2008GB003414. nd SJ0609 2006-07-20 20 nd 5.6 -45.6 0 nd 33.7 nd 0.03 0.09 2 North Atlantic ash/hydrolysis Sohm; J. A.; and Capone; D. G. (2010); Zonal differences in phosphorus pools; turnover and deficiency across the tropical North Atlantic Ocean; Global Biogeochem. Cycles; 24; GB2008; doi:10.1029/2008GB003414. nd SJ0609 2006-07-23 22 nd 9.5 -52.9 0 nd 34.7 nd 0.06 0.23 2 North Atlantic ash/hydrolysis Sohm; J. A.; and Capone; D. G. (2010); Zonal differences in phosphorus pools; turnover and deficiency across the tropical North Atlantic Ocean; Global Biogeochem. Cycles; 24; GB2008; doi:10.1029/2008GB003414. nd SJ0609 2006-07-24 23 nd 11.4 -56.4 0 nd 33 nd 0.01 0.18 2 North Atlantic ash/hydrolysis Sohm; J. A.; and Capone; D. G. (2010); Zonal differences in phosphorus pools; turnover and deficiency across the tropical North Atlantic Ocean; Global Biogeochem. Cycles; 24; GB2008; doi:10.1029/2008GB003414. nd GB 93 nd 1 nd 40.58 -70.67 5 nd nd nd nd 0.11 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd GB 93 nd 1 nd 40.58 -70.67 15 nd nd nd nd 0.14 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd GB 93 nd 2 nd 41 -68.92 0 nd nd nd nd 0.14 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd GB 93 nd 2 nd 41 -68.92 7 nd nd nd nd 0.15 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd GB 93 nd 2 nd 41 -68.92 60 nd nd nd nd 0.09 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd GB 93 nd 2 nd 41 -68.92 150 nd nd nd nd 0.05 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd GB 93 nd 2 nd 41 -68.92 250 nd nd nd nd 0.06 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd GB 93 nd 2 nd 41 -68.92 250 nd nd nd nd 0.06 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd GB 93 nd 3 nd 42.42 -67.5 0 nd nd nd nd 0.10 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd GB 93 nd 4 nd 41.5 -67 0 nd nd nd nd 0.19 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd GB 93 nd 4 nd 41.5 -67 5 nd nd nd nd 0.10 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd GB 93 nd 4 nd 41.5 -67 20 nd nd nd nd 0.12 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd GB 93 nd 5 nd 40.5 -67.67 0 nd nd nd nd 0.17 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd GB 93 nd 5 nd 40.5 -67.67 200 nd nd nd nd 0.06 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd GB 93 nd 5 nd 40.5 -67.67 400 nd nd nd nd 0.03 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd GB 93 nd 5 nd 40.5 -67.67 600 nd nd nd nd 0.03 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd GB 93 nd 5 nd 40.5 -67.67 800 nd nd nd nd 0.03 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd GB 93 nd 5 nd 40.5 -67.67 1000 nd nd nd nd 0.02 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd GB 93 nd 5 nd 40.5 -67.67 1500 nd nd nd nd 0.02 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd GB 93 nd 6 nd 40.92 -68.5 15 nd nd nd nd 0.16 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 16 nd 39.628 -71.623 752 nd nd nd nd 0.07 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 16 nd 39.628 -71.623 112 nd nd nd nd 0.10 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 16 nd 39.628 -71.623 500 nd nd nd nd 0.02 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 16 nd 39.628 -71.623 493 nd nd nd nd 0.03 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 16 nd 39.628 -71.623 50 nd nd nd nd 0.08 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 16 nd 39.628 -71.623 70 nd nd nd nd 0.12 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 16 nd 39.628 -71.623 20 nd nd nd nd 0.12 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 16 nd 39.628 -71.623 40 nd nd nd nd 0.14 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 7 nd 40.116 -70.35 100 nd nd nd nd 0.19 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 7 nd 40.116 -70.35 40 nd nd nd nd 0.16 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 7 nd 40.116 -70.35 61 nd nd nd nd 0.14 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 7 nd 40.116 -70.35 2 nd nd nd nd 0.16 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 4 nd 40.614 -70.354 52 nd nd nd nd 0.10 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 4 nd 40.614 -70.354 40 nd nd nd nd 0.09 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 4 nd 40.614 -70.354 25 nd nd nd nd 0.19 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 4 nd 40.614 -70.354 25 nd nd nd nd 0.14 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 6 nd 40.283 -70.351 100 nd nd nd nd 0.08 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 6 nd 40.283 -70.351 36 nd nd nd nd 0.13 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 6 nd 40.283 -70.351 20 nd nd nd nd 0.10 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 6 nd 40.283 -70.351 5 nd nd nd nd 0.10 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 6 nd 40.283 -70.351 70 nd nd nd nd 0.06 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 3 nd 40.785 -70.352 25 nd nd nd nd 0.12 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 3 nd 40.785 -70.352 2 nd nd nd nd 0.23 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 3 nd 40.785 -70.352 36 nd nd nd nd 0.08 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 3 nd 40.785 -70.352 12 nd nd nd nd 0.20 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 3 nd 40.785 -70.352 3 nd nd nd nd 0.16 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 12 nd 40.323 -72.034 62 nd nd nd nd 0.23 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 12 nd 40.323 -72.034 56 nd nd nd nd 0.25 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 12 nd 40.323 -72.034 40 nd nd nd nd 0.20 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 12 nd 40.323 -72.034 35 nd nd nd nd 0.16 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 12 nd 40.323 -72.034 26 nd nd nd nd 0.23 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 12 nd 40.323 -72.034 31 nd nd nd nd 0.14 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 12 nd 40.323 -72.034 16 nd nd nd nd 0.13 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 12 nd 40.323 -72.034 15 nd nd nd nd 0.13 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 45 nd 37.32 -74.067 40 nd nd nd nd 0.10 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 45 nd 37.32 -74.067 35 nd nd nd nd 0.24 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 45 nd 37.32 -74.067 20 nd nd nd nd 0.21 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 45 nd 37.32 -74.067 15 nd nd nd nd 0.28 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 45 nd 37.32 -74.067 10 nd nd nd nd 0.22 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 45 nd 37.32 -74.067 5 nd nd nd nd 0.21 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 45 nd 37.32 -74.067 3 nd nd nd nd 0.23 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 45 nd 37.32 -74.067 2 nd nd nd nd 0.23 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 43 nd 37.444 -74.841 65 nd nd nd nd 0.21 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 43 nd 37.444 -74.841 40 nd nd nd nd 0.19 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 43 nd 37.444 -74.841 24 nd nd nd nd 0.14 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 43 nd 37.444 -74.841 20 nd nd nd nd 0.23 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 43 nd 37.444 -74.841 18 nd nd nd nd 0.14 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 43 nd 37.444 -74.841 10 nd nd nd nd 0.20 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 43 nd 37.444 -74.841 2 nd nd nd nd 0.16 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 43 nd 37.444 -74.841 2 nd nd nd nd 0.12 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 19 nd 39.111 -73.29 1 nd nd nd nd 0.17 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 15 nd 39.8 -71.727 30 nd nd nd nd 0.25 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 15 nd 39.8 -71.727 1 nd nd nd nd 0.23 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 15 nd 39.8 -71.727 16 nd nd nd nd 0.15 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 15 nd 39.8 -71.727 5 nd nd nd nd 0.14 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 40 nd 37 -75.2 16 nd nd nd nd 0.24 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 40 nd 37 -75.2 12 nd nd nd nd 0.23 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 42 nd 37.507 -74.983 20 nd nd nd nd 0.13 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 42 nd 37.507 -74.983 15 nd nd nd nd 0.14 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 1 nd 41.116 -70.348 15 nd nd nd nd 0.18 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 1 nd 41.116 -70.348 15 nd nd nd nd 0.15 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 1 nd 41.116 -70.348 20 nd nd nd nd 0.20 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 1 nd 41.116 -70.348 4 nd nd nd nd 0.18 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 21 nd 39.373 -73.8 15 nd nd nd nd 0.20 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 21 nd 39.373 -73.8 1 nd nd nd nd 0.16 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 53 nd 36.616 -75.61 9 nd nd nd nd 0.18 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 53 nd 36.616 -75.61 4 nd nd nd nd 0.19 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 53 nd 36.616 -75.61 2 nd nd nd nd 0.21 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 39 nd 37.723 -75.407 16 nd nd nd nd 0.21 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 39 nd 37.723 -75.407 2 nd nd nd nd 0.24 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 39 nd 37.723 -75.407 11 nd nd nd nd 0.22 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 22 nd 39.508 -74.084 15 nd nd nd nd 0.25 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 22 nd 39.508 -74.084 10 nd nd nd nd 0.15 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 22 nd 39.508 -74.084 2 nd nd nd nd 0.17 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 47 nd 36.617 -74.399 11 nd nd nd nd 0.18 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 47 nd 36.617 -74.399 2 nd nd nd nd 0.29 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 49 nd 36.617 -74.8 11 nd nd nd nd 0.28 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 94 nd 51 nd 36.616 -75.207 11 nd nd nd nd 0.35 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 1 nd 35.448 -75.381 19 nd nd nd nd 0.18 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 1 nd 35.448 -75.381 15 nd nd nd nd 0.22 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 1 nd 35.448 -75.381 13 nd nd nd nd 0.29 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 1 nd 35.448 -75.381 10 nd nd nd nd 0.24 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 1 nd 35.448 -75.381 5 nd nd nd nd 0.24 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 2 nd 35.448 -75.228 32 nd nd nd nd 0.24 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 2 nd 35.448 -75.228 25 nd nd nd nd 0.20 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 2 nd 35.448 -75.228 20 nd nd nd nd 0.22 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 2 nd 35.448 -75.228 15 nd nd nd nd 0.20 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 2 nd 35.448 -75.228 4 nd nd nd nd 0.30 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 3 nd 35.454 -75.057 36 nd nd nd nd 0.20 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 3 nd 35.454 -75.057 31 nd nd nd nd 0.18 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 3 nd 35.454 -75.057 20 nd nd nd nd 0.17 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 3 nd 35.454 -75.057 15 nd nd nd nd 0.25 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 3 nd 35.454 -75.057 10 nd nd nd nd 0.27 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 3 nd 35.454 -75.057 5 nd nd nd nd 0.30 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 4 nd 35.448 -74.882 75 nd nd nd nd 0.22 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 4 nd 35.448 -74.882 46 nd nd nd nd 0.20 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 4 nd 35.448 -74.882 35 nd nd nd nd 0.22 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 4 nd 35.448 -74.882 25 nd nd nd nd 0.23 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 4 nd 35.448 -74.882 15 nd nd nd nd 0.25 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 4 nd 35.448 -74.882 3 nd nd nd nd 0.24 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 5 nd 35.447 -74.721 50 nd nd nd nd 0.18 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 5 nd 35.447 -74.721 35 nd nd nd nd 0.16 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 5 nd 35.447 -74.721 25 nd nd nd nd 0.15 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 5 nd 35.447 -74.721 15 nd nd nd nd 0.16 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 5 nd 35.447 -74.721 3 nd nd nd nd 0.17 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 5 nd 35.447 -74.721 1501 nd nd nd nd 0.06 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 5 nd 35.447 -74.721 1001 nd nd nd nd 0.08 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 5 nd 35.447 -74.721 750 nd nd nd nd 0.08 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 5 nd 35.447 -74.721 501 nd nd nd nd 0.05 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 5 nd 35.447 -74.721 399 nd nd nd nd 0.04 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 5 nd 35.447 -74.721 299 nd nd nd nd 0.05 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 5 nd 35.447 -74.721 202 nd nd nd nd 0.07 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 5 nd 35.447 -74.721 101 nd nd nd nd 0.10 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 5 nd 35.447 -74.721 81 nd nd nd nd 0.08 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 5 nd 35.447 -74.721 70 nd nd nd nd 0.06 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 5 nd 35.447 -74.721 16 nd nd nd nd 0.31 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 5 nd 35.447 -74.721 10 nd nd nd nd 0.24 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 9 nd 36.7 -75.288 28 nd nd nd nd 0.20 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 9 nd 36.7 -75.288 24 nd nd nd nd 0.20 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 9 nd 36.7 -75.288 15 nd nd nd nd 0.19 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 9 nd 36.7 -75.288 5 nd nd nd nd 0.20 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 9 nd 36.7 -75.288 16 nd nd nd nd 0.22 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 9 nd 36.7 -75.288 4 nd nd nd nd 0.21 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 10 nd 36.7 -75.101 33 nd nd nd nd 0.19 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 10 nd 36.7 -75.101 25 nd nd nd nd 0.20 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 10 nd 36.7 -75.101 20 nd nd nd nd 0.12 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 10 nd 36.7 -75.101 15 nd nd nd nd 0.24 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 10 nd 36.7 -75.101 8 nd nd nd nd 0.24 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 11 nd 36.7 -74.797 62 nd nd nd nd 0.13 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 11 nd 36.7 -74.797 45 nd nd nd nd 0.10 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 11 nd 36.7 -74.797 35 nd nd nd nd 0.15 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 11 nd 36.7 -74.797 20 nd nd nd nd 0.19 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 11 nd 36.7 -74.797 10 nd nd nd nd 0.22 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 11 nd 36.7 -74.797 3 nd nd nd nd 0.22 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 12 nd 36.699 -74.584 60 nd nd nd nd 0.09 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 12 nd 36.699 -74.584 41 nd nd nd nd 0.12 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 12 nd 36.699 -74.584 30 nd nd nd nd 0.14 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 12 nd 36.699 -74.584 20 nd nd nd nd 0.17 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 12 nd 36.699 -74.584 10 nd nd nd nd 0.22 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 12 nd 36.699 -74.584 5 nd nd nd nd 0.18 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 12 nd 36.699 -74.584 1000 nd nd nd nd 0.02 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 12 nd 36.699 -74.584 751 nd nd nd nd 0.06 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 12 nd 36.699 -74.584 501 nd nd nd nd 0.02 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 12 nd 36.699 -74.584 400 nd nd nd nd 0.00 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 12 nd 36.699 -74.584 200 nd nd nd nd 0.07 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 12 nd 36.699 -74.584 101 nd nd nd nd 0.04 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 13 nd 37.581 -73.933 60 nd nd nd nd 0.08 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 13 nd 37.581 -73.933 1500 nd nd nd nd 0.04 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 13 nd 37.581 -73.933 1001 nd nd nd nd 0.02 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 13 nd 37.581 -73.933 500 nd nd nd nd 0.05 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 13 nd 37.581 -73.933 399 nd nd nd nd 0.01 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 13 nd 37.581 -73.933 200 nd nd nd nd 0.02 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 13 nd 37.581 -73.933 100 nd nd nd nd 0.08 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 13 nd 37.581 -73.933 51 nd nd nd nd 0.07 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 13 nd 37.581 -73.933 41 nd nd nd nd 0.11 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 13 nd 37.581 -73.933 30 nd nd nd nd 0.15 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 13 nd 37.581 -73.933 20 nd nd nd nd 0.19 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 13 nd 37.581 -73.933 3 nd nd nd nd 0.21 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 14 nd 37.667 -74.134 62 nd nd nd nd 0.08 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 14 nd 37.667 -74.134 33 nd nd nd nd 0.17 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 14 nd 37.667 -74.134 30 nd nd nd nd 0.20 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 14 nd 37.667 -74.134 20 nd nd nd nd 0.25 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 14 nd 37.667 -74.134 10 nd nd nd nd 0.24 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 14 nd 37.667 -74.134 3 nd nd nd nd 0.22 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 14 nd 37.667 -74.134 995 nd nd nd nd 0.07 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 14 nd 37.667 -74.134 743 nd nd nd nd 0.02 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 14 nd 37.667 -74.134 501 nd nd nd nd 0.00 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 14 nd 37.667 -74.134 300 nd nd nd nd 0.02 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 14 nd 37.667 -74.134 200 nd nd nd nd 0.09 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 14 nd 37.667 -74.134 100 nd nd nd nd 0.06 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 14 nd 37.667 -74.134 89 nd nd nd nd 0.08 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 15 nd 37.75 -74.349 60 nd nd nd nd 0.07 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 15 nd 37.75 -74.349 29 nd nd nd nd 0.14 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 15 nd 37.75 -74.349 15 nd nd nd nd 0.15 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 15 nd 37.75 -74.349 9 nd nd nd nd 0.20 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 15 nd 37.75 -74.349 3 nd nd nd nd 0.18 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 16 nd 37.835 -74.564 45 nd nd nd nd 0.14 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 16 nd 37.835 -74.564 35 nd nd nd nd 0.14 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 16 nd 37.835 -74.564 25 nd nd nd nd 0.16 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 16 nd 37.835 -74.564 3 nd nd nd nd 0.28 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 17 nd 37.917 -74.77 31 nd nd nd nd 0.06 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 17 nd 37.917 -74.77 25 nd nd nd nd 0.00 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 17 nd 37.917 -74.77 20 nd nd nd nd 0.06 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 17 nd 37.917 -74.77 15 nd nd nd nd 0.29 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 17 nd 37.917 -74.77 10 nd nd nd nd 0.29 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 17 nd 37.917 -74.77 4 nd nd nd nd 0.28 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 18 nd 38.002 -74.972 22 nd nd nd nd 0.30 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 18 nd 38.002 -74.972 15 nd nd nd nd 0.30 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 18 nd 38.002 -74.972 4 nd nd nd nd 0.35 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 19 nd 38.486 -72.999 200 nd nd nd nd 0.01 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 19 nd 38.486 -72.999 100 nd nd nd nd 0.02 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 19 nd 38.486 -72.999 50 nd nd nd nd 0.04 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 19 nd 38.486 -72.999 40 nd nd nd nd 0.14 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 19 nd 38.486 -72.999 20 nd nd nd nd 0.12 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 19 nd 38.486 -72.999 3 nd nd nd nd 0.10 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 20 nd 38.667 -73.134 171 nd nd nd nd 0.00 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 20 nd 38.667 -73.134 101 nd nd nd nd 0.02 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 20 nd 38.667 -73.134 51 nd nd nd nd 0.06 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 20 nd 38.667 -73.134 30 nd nd nd nd 0.07 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 20 nd 38.667 -73.134 15 nd nd nd nd 0.09 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 20 nd 38.667 -73.134 2 nd nd nd nd 0.12 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 21 nd 38.801 -73.281 75 nd nd nd nd 0.00 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 21 nd 38.801 -73.281 50 nd nd nd nd 0.03 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 21 nd 38.801 -73.281 36 nd nd nd nd 0.10 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 21 nd 38.801 -73.281 25 nd nd nd nd 0.13 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 21 nd 38.801 -73.281 4 nd nd nd nd 0.21 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 22 nd 38.934 -73.416 65 nd nd nd nd 0.07 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 22 nd 38.934 -73.416 49 nd nd nd nd 0.02 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 22 nd 38.934 -73.416 35 nd nd nd nd 0.04 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 22 nd 38.934 -73.416 25 nd nd nd nd 0.13 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 22 nd 38.934 -73.416 15 nd nd nd nd 0.17 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 23 nd 39.079 -73.551 42 nd nd nd nd 0.10 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 23 nd 39.079 -73.551 35 nd nd nd nd 0.14 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 23 nd 39.079 -73.551 30 nd nd nd nd 0.10 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 23 nd 39.079 -73.551 25 nd nd nd nd 0.17 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 23 nd 39.079 -73.551 20 nd nd nd nd 0.22 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 23 nd 39.079 -73.551 14 nd nd nd nd 0.22 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 23 nd 39.079 -73.551 10 nd nd nd nd 0.30 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 23 nd 39.079 -73.551 4 nd nd nd nd 0.23 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 24 nd 39.214 -73.7 41 nd nd nd nd 0.08 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 24 nd 39.214 -73.7 31 nd nd nd nd 0.12 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 24 nd 39.214 -73.7 25 nd nd nd nd 0.14 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 24 nd 39.214 -73.7 20 nd nd nd nd 0.23 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 24 nd 39.214 -73.7 15 nd nd nd nd 0.29 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 24 nd 39.214 -73.7 3 nd nd nd nd 0.25 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 25 nd 39.35 -73.835 37 nd nd nd nd 0.16 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 25 nd 39.35 -73.835 25 nd nd nd nd 0.16 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 25 nd 39.35 -73.835 20 nd nd nd nd 0.23 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 25 nd 39.35 -73.835 15 nd nd nd nd 0.31 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 25 nd 39.35 -73.835 10 nd nd nd nd 0.23 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 25 nd 39.35 -73.835 23 nd nd nd nd 0.16 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 25 nd 39.35 -73.835 16 nd nd nd nd 0.22 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 26 nd 39.499 -73.968 22 nd nd nd nd 0.15 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 26 nd 39.499 -73.968 16 nd nd nd nd 0.16 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 26 nd 39.499 -73.968 10 nd nd nd nd 0.15 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 26 nd 39.499 -73.968 4 nd nd nd nd 0.14 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 28 nd 40.702 -72.252 46 nd nd nd nd 0.09 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 28 nd 40.702 -72.252 41 nd nd nd nd 0.07 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 28 nd 40.702 -72.252 35 nd nd nd nd 0.04 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 28 nd 40.702 -72.252 30 nd nd nd nd 0.03 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 28 nd 40.702 -72.252 25 nd nd nd nd 0.07 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 28 nd 40.702 -72.252 21 nd nd nd nd 0.08 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 28 nd 40.702 -72.252 14 nd nd nd nd 0.12 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 28 nd 40.702 -72.252 10 nd nd nd nd 0.12 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 29 nd 40.533 -72.15 58 nd nd nd nd 0.07 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 29 nd 40.533 -72.15 50 nd nd nd nd 0.05 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 29 nd 40.533 -72.15 46 nd nd nd nd 0.08 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 29 nd 40.533 -72.15 41 nd nd nd nd 0.04 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 29 nd 40.533 -72.15 31 nd nd nd nd 0.03 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 29 nd 40.533 -72.15 25 nd nd nd nd 0.20 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 29 nd 40.533 -72.15 21 nd nd nd nd 0.26 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 29 nd 40.533 -72.15 15 nd nd nd nd 0.23 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 29 nd 40.533 -72.15 10 nd nd nd nd 0.23 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 29 nd 40.533 -72.15 4 nd nd nd nd 0.44 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 30 nd 40.33 -72.031 63 nd nd nd nd 0.13 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 30 nd 40.33 -72.031 55 nd nd nd nd 0.17 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 30 nd 40.33 -72.031 45 nd nd nd nd 0.06 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 30 nd 40.33 -72.031 40 nd nd nd nd 0.12 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 30 nd 40.33 -72.031 35 nd nd nd nd 0.19 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 30 nd 40.33 -72.031 30 nd nd nd nd 0.24 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 30 nd 40.33 -72.031 25 nd nd nd nd 0.21 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 30 nd 40.33 -72.031 20 nd nd nd nd 0.23 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 30 nd 40.33 -72.031 15 nd nd nd nd 0.24 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 30 nd 40.33 -72.031 10 nd nd nd nd 0.30 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 30 nd 40.33 -72.031 3 nd nd nd nd 0.24 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 31 nd 40.147 -71.933 76 nd nd nd nd 0.04 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 31 nd 40.147 -71.933 67 nd nd nd nd 0.01 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 31 nd 40.147 -71.933 50 nd nd nd nd 0.02 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 31 nd 40.147 -71.933 40 nd nd nd nd 0.04 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 31 nd 40.147 -71.933 35 nd nd nd nd 0.07 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 31 nd 40.147 -71.933 30 nd nd nd nd 0.08 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 31 nd 40.147 -71.933 26 nd nd nd nd 0.09 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 31 nd 40.147 -71.933 21 nd nd nd nd 0.09 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 31 nd 40.147 -71.933 15 nd nd nd nd 0.06 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 31 nd 40.147 -71.933 10 nd nd nd nd 0.10 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 31 nd 40.147 -71.933 4 nd nd nd nd 0.08 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 32 nd 39.983 -71.832 96 nd nd nd nd 0.07 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 32 nd 39.983 -71.832 75 nd nd nd nd 0.13 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 32 nd 39.983 -71.832 65 nd nd nd nd 0.03 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 32 nd 39.983 -71.832 56 nd nd nd nd 0.03 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 32 nd 39.983 -71.832 45 nd nd nd nd 0.07 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 32 nd 39.983 -71.832 35 nd nd nd nd 0.08 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 32 nd 39.983 -71.832 25 nd nd nd nd 0.07 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 32 nd 39.983 -71.832 20 nd nd nd nd 0.10 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 32 nd 39.983 -71.832 16 nd nd nd nd 0.10 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 32 nd 39.983 -71.832 10 nd nd nd nd 0.14 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 32 nd 39.983 -71.832 4 nd nd nd nd 0.05 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 33 nd 39.818 -71.733 60 nd nd nd nd 0.04 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 33 nd 39.818 -71.733 51 nd nd nd nd 0.03 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 33 nd 39.818 -71.733 45 nd nd nd nd 0.12 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 33 nd 39.818 -71.733 40 nd nd nd nd 0.12 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 33 nd 39.818 -71.733 36 nd nd nd nd 0.13 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 33 nd 39.818 -71.733 30 nd nd nd nd 0.12 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 33 nd 39.818 -71.733 25 nd nd nd nd 0.11 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 33 nd 39.818 -71.733 20 nd nd nd nd 0.12 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 33 nd 39.818 -71.733 15 nd nd nd nd 0.08 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 33 nd 39.818 -71.733 10 nd nd nd nd 0.06 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 33 nd 39.818 -71.733 3 nd nd nd nd 0.09 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 33 nd 39.818 -71.733 463 nd nd nd nd 0.01 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 33 nd 39.818 -71.733 401 nd nd nd nd 0.00 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 33 nd 39.818 -71.733 350 nd nd nd nd 0.00 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 33 nd 39.818 -71.733 300 nd nd nd nd 0.00 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 33 nd 39.818 -71.733 250 nd nd nd nd 0.00 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 33 nd 39.818 -71.733 200 nd nd nd nd 0.00 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 33 nd 39.818 -71.733 150 nd nd nd nd 0.00 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 33 nd 39.818 -71.733 125 nd nd nd nd 0.00 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 33 nd 39.818 -71.733 100 nd nd nd nd 0.00 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 33 nd 39.818 -71.733 75 nd nd nd nd 0.01 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 33 nd 39.818 -71.733 59 nd nd nd nd 0.06 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 34 nd 39.633 -71.632 1163 nd nd nd nd 0.02 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 34 nd 39.633 -71.632 1011 nd nd nd nd 0.03 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 34 nd 39.633 -71.632 748 nd nd nd nd 0.01 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 34 nd 39.633 -71.632 505 nd nd nd nd 0.00 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 34 nd 39.633 -71.632 404 nd nd nd nd 0.00 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 34 nd 39.633 -71.632 303 nd nd nd nd 0.01 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 34 nd 39.633 -71.632 202 nd nd nd nd 0.00 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 34 nd 39.633 -71.632 101 nd nd nd nd 0.00 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 34 nd 39.633 -71.632 81 nd nd nd nd 0.00 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 34 nd 39.633 -71.632 71 nd nd nd nd 0.01 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 34 nd 39.633 -71.632 60 nd nd nd nd 0.00 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 34 nd 39.633 -71.632 50 nd nd nd nd 0.00 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 34 nd 39.633 -71.632 40 nd nd nd nd 0.06 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 34 nd 39.633 -71.632 35 nd nd nd nd 0.10 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 34 nd 39.633 -71.632 30 nd nd nd nd 0.12 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 34 nd 39.633 -71.632 25 nd nd nd nd 0.12 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 34 nd 39.633 -71.632 20 nd nd nd nd 0.11 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 34 nd 39.633 -71.632 15 nd nd nd nd 0.12 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 34 nd 39.633 -71.632 9 nd nd nd nd 0.11 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 34 nd 39.633 -71.632 4 nd nd nd nd 0.06 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 36 nd 40.922 -70.361 101 nd nd nd nd 0.02 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 36 nd 40.922 -70.361 74 nd nd nd nd 0.03 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 36 nd 40.922 -70.361 60 nd nd nd nd 0.04 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 36 nd 40.922 -70.361 50 nd nd nd nd 0.00 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 36 nd 40.922 -70.361 39 nd nd nd nd 0.00 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. 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Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 35 nd 40.784 -70.351 11 nd nd nd nd 0.10 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 nd MAB 96 nd 35 nd 40.784 -70.351 4 nd nd nd nd 0.15 2 North Atlantic UV oxidation Hopkinson; C.; Vallino; J. Efficient export of carbon to the deep ocean through dissolved organic matter. Nature 433; 142 145 (2005). https://doi.org/10.1038/nature03191 33RO20161119 GO-SHIP P18-2016 2016-11-25 5 19 22.0021 -109.9999 204.9 12.5037 34.759 24.65 2.70 0.23 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-11-25 5 20 22.0021 -109.9999 145.1 13.7713 34.7494 24.13 2.64 0.20 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-11-25 5 21 22.0021 -109.9999 95 16.6464 34.5417 20.55 2.14 0.31 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-11-25 5 22 22.0021 -109.9999 50.2 25.2345 34.1591 0.02 0.33 0.34 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-11-25 5 23 22.0021 -109.9999 19.9 27.6201 34.5336 0.01 0.31 0.49 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-11-26 9 19 20.0002 -110 194 12.2768 34.7671 23.57 2.70 0.30 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-11-26 9 20 20.0002 -110 144.9 13.3468 34.7602 23.28 2.68 0.18 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-11-26 9 23 20.0002 -110 25.1 28.0887 34.4826 0.11 0.35 0.38 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-11-26 9 24 20.0002 -110 3 28.0725 34.4671 0.42 0.33 0.40 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-11-27 13 17 18.0002 -110.0004 185.9 12.8369 34.7575 23.72 2.70 0.16 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-11-27 13 19 18.0002 -110.0004 120.6 15.3117 34.607 22.58 2.39 0.29 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-11-27 13 21 18.0002 -110.0004 80.5 18.9716 34.2417 3.59 0.93 0.38 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-11-27 13 22 18.0002 -110.0004 60.1 22.9931 34.3981 0.01 0.38 0.36 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-11-27 13 23 18.0002 -110.0004 30.2 28.3803 34.2933 0.01 0.27 0.30 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-11-27 13 24 18.0002 -110.0004 2.8 28.7665 34.059 0.01 0.21 0.42 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-11-28 17 20 16.0014 -109.9998 145.2 13.1668 34.7546 24.40 2.64 0.13 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-11-28 17 21 16.0014 -109.9998 95.2 16.3585 34.6279 23.42 2.38 0.50 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-11-28 17 22 16.0014 -109.9998 50.2 25.1648 34.3972 0.50 0.59 0.39 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-11-28 17 23 16.0014 -109.9998 40 28.246 34.1597 0.04 0.31 0.34 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-11-29 21 19 14 -110.0001 230.4 11.1308 34.7193 28.73 2.66 0.26 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-11-29 21 20 14 -110.0001 165.1 11.9709 34.7545 27.74 2.61 0.14 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-11-29 21 21 14 -110.0001 109.6 13.7309 34.7655 24.03 2.58 0.13 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-11-29 21 22 14 -110.0001 60.2 21.0916 34.5082 15.79 1.58 0.24 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-11-29 21 23 14 -110.0001 24.9 29.44 33.6187 0.02 0.19 0.35 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-11-29 21 24 14 -110.0001 2.2 29.4222 33.5638 0.02 0.17 0.30 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-11-30 25 20 11.9998 -110.0006 184.6 11.9047 34.7729 31.85 2.50 0.18 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-11-30 25 21 11.9998 -110.0006 124.2 12.8393 34.7954 30.10 2.48 0.10 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-11-30 25 22 11.9998 -110.0006 70 17.3905 34.6312 25.95 2.22 0.20 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-11-30 25 23 11.9998 -110.0006 29.8 28.2557 33.1268 0.03 0.16 0.40 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-11-30 25 24 11.9998 -110.0006 3 28.328 33.0691 0.03 0.15 0.35 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-01 29 21 10.0001 -109.9998 95.2 13.3375 34.8115 31.73 2.41 0.13 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-01 29 22 10.0001 -109.9998 49.9 18.4728 34.5954 22.64 2.02 0.18 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-01 29 23 10.0001 -109.9998 20.9 27.832 32.7357 0.02 0.15 0.39 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-01 29 24 10.0001 -109.9998 2.8 28.009 32.7092 0.01 0.15 0.31 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-02 33 19 7.9998 -110 249.3 10.814 34.7258 34.61 2.55 0.11 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-02 33 20 7.9998 -110 178.5 11.5072 34.7518 33.28 2.53 0.11 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-02 33 21 7.9998 -110 114.9 13.0406 34.8159 30.10 2.50 0.38 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-02 33 22 7.9998 -110 59.2 23.3315 34.4891 7.69 0.91 0.39 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-02 33 23 7.9998 -110 24.5 27.8682 32.0945 0.01 0.13 0.24 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-02 33 24 7.9998 -110 3.1 27.6733 31.7985 0.01 0.11 0.25 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-03 37 20 5.9999 -109.9999 204.2 11.3673 34.7443 32.86 2.36 0.04 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-03 37 21 5.9999 -109.9999 139.1 13.9179 34.7576 29.57 2.16 0.06 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-03 37 22 5.9999 -109.9999 70.2 25.0186 34.0357 2.55 0.44 0.31 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-03 37 23 5.9999 -109.9999 28.9 26.6392 33.6546 0.11 0.19 0.29 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-03 37 24 5.9999 -109.9999 2.7 26.6378 33.6538 0.11 0.19 0.21 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-04 41 19 4 -110 249.9 12.143 34.8402 31.52 2.18 0.09 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-04 41 20 4 -110 171.4 12.9975 34.903 29.88 2.08 0.10 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-04 41 21 4 -110 105.8 14.38 34.7949 24.13 1.71 0.25 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-04 41 22 4 -110 50.1 25.8654 33.5953 0.54 0.21 0.25 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-04 41 23 4 -110 20.6 25.8846 33.606 0.43 0.21 0.33 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-04 41 24 4 -110 3.7 25.8806 33.6042 0.43 0.21 0.31 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-11 73 20 -5.5901 -109.1799 195.6 13.0418 34.9395 32.65 2.37 0.09 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-11 73 21 -5.5901 -109.1799 135.5 13.6232 34.9665 28.55 2.05 0.12 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-11 73 23 -5.5901 -109.1799 30.1 24.2626 35.2066 7.32 0.75 0.30 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-11 73 24 -5.5901 -109.1799 4.6 24.4229 35.1925 7.32 0.74 0.43 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-11 75 19 -6.1799 -108.3499 225.3 12.3984 34.8897 29.88 2.43 0.10 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-11 75 20 -6.1799 -108.3499 164.9 14.0028 34.9657 24.03 2.14 0.12 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-11 75 21 -6.1799 -108.3499 107.1 22.0545 35.3062 10.09 1.10 0.36 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-11 75 22 -6.1799 -108.3499 59.7 24.4714 35.3586 7.23 0.75 0.27 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-11 75 23 -6.1799 -108.3499 24.8 24.5664 35.2973 8.06 0.80 0.28 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-11 75 24 -6.1799 -108.3499 3.1 24.5704 35.2884 8.16 0.79 0.42 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-14 87 20 -9.71 -103.41 205.7 12.6364 34.8401 23.30 2.68 0.11 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-14 87 22 -9.71 -103.41 60.2 24.1847 35.9342 1.17 0.39 0.35 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-14 87 23 -9.71 -103.41 23.9 24.3639 35.5405 6.18 0.64 0.24 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-14 87 24 -9.71 -103.41 3.3 24.3541 35.5389 6.18 0.64 0.26 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-16 95 20 -13.5 -103 183.6 16.4334 35.1368 11.82 1.25 0.22 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-16 95 21 -13.5 -103 104.4 22.048 36.02 0.17 0.48 0.34 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-16 95 22 -13.5 -103 48.5 24.2796 35.9296 1.18 0.43 0.41 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-16 95 23 -13.5 -103 19.2 24.3381 35.9037 1.60 0.45 0.36 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-16 95 24 -13.5 -103 3 24.3258 35.897 1.60 0.46 0.33 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-17 99 20 -15.5004 -103 199.1 16.5386 35.1109 11.82 1.19 0.11 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-17 99 21 -15.5004 -103 120.2 21.8082 36.0343 1.07 0.50 0.28 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-17 99 22 -15.5004 -103 60 22.8151 36.1597 0.01 0.36 0.26 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-17 99 23 -15.5004 -103 26.3 24.0126 36.0665 0.95 0.40 0.28 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-17 99 24 -15.5004 -103 3.1 24.0415 36.075 0.95 0.39 0.30 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-18 103 20 -17.4999 -103 230.7 16.4917 35.1022 9.24 0.97 0.11 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-18 103 21 -17.4999 -103 165.8 20.099 35.7215 5.44 0.76 0.17 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-18 103 22 -17.4999 -103 85 22.316 36.124 0.12 0.39 0.28 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-18 103 23 -17.4999 -103 34.4 23.5705 36.1683 0.12 0.32 0.31 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-18 103 24 -17.4999 -103 3.4 23.8331 36.1586 0.22 0.34 0.25 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-19 107 19 -19.5001 -103 249.2 17.6969 35.2925 6.27 0.78 0.16 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-19 107 20 -19.5001 -103 171.2 21.6656 36.0932 0.74 0.42 0.18 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-19 107 21 -19.5001 -103 105.9 22.97 36.3142 0.00 0.35 0.23 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-19 107 22 -19.5001 -103 48.5 23.6501 36.3825 0.00 0.37 0.18 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-19 107 23 -19.5001 -103 18.8 23.8736 36.397 0.00 0.38 0.20 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-19 107 24 -19.5001 -103 2.9 23.8834 36.3999 0.00 0.37 0.31 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-20 111 20 -21.5 -103 200.4 20.1659 35.7766 0.38 0.34 0.16 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-20 111 21 -21.5 -103 125 22.5433 36.2543 0.01 0.34 0.20 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-20 111 22 -21.5 -103 59.9 23.6223 36.3909 0.00 0.36 0.30 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-20 111 23 -21.5 -103 15.4 24.2378 36.4784 0.01 0.37 0.17 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-20 111 24 -21.5 -103 3 24.235 36.4768 0.01 0.37 0.39 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-21 115 20 -23.4995 -103.0006 217.1 18.0474 35.3025 0.41 0.37 0.18 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-21 115 21 -23.4995 -103.0006 144.3 20.7573 35.8511 0.00 0.21 0.21 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-21 115 22 -23.4995 -103.0006 69.1 22.1958 36.0911 0.00 0.24 0.14 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-21 115 23 -23.4995 -103.0006 40.1 23.6216 36.2841 0.00 0.24 0.25 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2016-12-21 115 24 -23.4995 -103.0006 3 24.4722 36.3261 0.00 0.24 0.19 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-01 119 20 -25.5 -101.4999 160.2 17.8756 35.2191 0.34 0.29 0.17 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-01 119 21 -25.5 -101.4999 94.9 20.7745 35.7195 0.01 0.18 0.19 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-01 119 22 -25.5 -101.4999 50.3 23.4058 36.173 0.01 0.22 0.22 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-01 119 23 -25.5 -101.4999 20.3 24.2378 36.2058 0.00 0.21 0.17 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-02 123 19 -27.5003 -101.5009 225.7 15.5508 34.8775 3.26 0.48 0.12 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-02 123 20 -27.5003 -101.5009 165.1 19.183 35.4982 0.01 0.21 0.15 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-02 123 21 -27.5003 -101.5009 110 20.1237 35.6359 0.00 0.20 0.15 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-02 123 22 -27.5003 -101.5009 60.4 21.9236 35.8244 0.01 0.20 0.09 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-02 123 23 -27.5003 -101.5009 25.2 23.257 35.8896 0.00 0.20 0.09 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-02 123 24 -27.5003 -101.5009 2.8 23.7281 35.8924 0.00 0.20 0.10 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-03 127 20 -29.5009 -102.9991 200.5 14.9085 34.7349 4.58 0.52 0.12 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-03 127 21 -29.5009 -102.9991 134.7 17.2875 34.9472 0.01 0.15 0.16 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-03 127 22 -29.5009 -102.9991 69.9 18.5469 35.039 0.01 0.14 0.23 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-03 127 23 -29.5009 -102.9991 30.1 22.1999 35.2272 0.01 0.16 0.18 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-03 127 24 -29.5009 -102.9991 2.8 22.9941 35.1385 0.01 0.14 0.26 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-05 131 19 -31.5 -103 220.8 13.9274 34.5636 7.41 0.65 0.10 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-05 131 20 -31.5 -103 154.9 16.4907 34.7835 0.37 0.21 0.18 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-05 131 21 -31.5 -103 95.3 17.3018 34.8374 0.22 0.15 0.14 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-05 131 22 -31.5 -103 50.1 18.8241 34.8495 0.20 0.15 0.19 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-05 131 23 -31.5 -103 20.4 21.7103 34.8531 0.20 0.17 0.12 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-05 131 24 -31.5 -103 2.6 22.3896 34.8556 0.20 0.17 0.17 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-05 135 19 -33.5014 -102.9987 249.9 9.3136 34.3045 17.36 1.30 0.08 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-05 135 20 -33.5014 -102.9987 180.2 11.5161 34.3655 12.14 1.00 0.13 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-05 135 21 -33.5014 -102.9987 114.8 13.691 34.3386 4.89 0.60 0.08 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-05 135 22 -33.5014 -102.9987 59.6 15.4584 34.3533 0.35 0.28 0.16 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-05 135 23 -33.5014 -102.9987 25.3 20.3951 34.3221 0.01 0.21 0.17 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-05 135 24 -33.5014 -102.9987 3.1 21.2886 34.3468 0.01 0.19 0.19 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-06 139 20 -35.501 -103.0027 184.8 11.2077 34.2812 12.78 1.02 0.04 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-06 139 21 -35.501 -103.0027 126 12.6147 34.0674 6.84 0.69 0.26 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-06 139 22 -35.501 -103.0027 70.5 14.2651 34.1358 2.67 0.41 0.25 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-06 139 23 -35.501 -103.0027 29.5 18.8908 34.1125 0.95 0.29 0.25 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-06 139 24 -35.501 -103.0027 3.2 21.3063 34.0336 1.26 0.32 0.30 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-07 143 19 -37.5003 -102.9994 219.5 9.3807 34.2264 17.89 1.32 BDL 3 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-07 143 20 -37.5003 -102.9994 154.4 11.3 34.1596 12.96 1.03 0.22 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-07 143 21 -37.5003 -102.9994 95.1 13.2792 34.07 4.82 0.59 0.26 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-07 143 22 -37.5003 -102.9994 50.2 14.9476 34.1694 1.81 0.37 0.32 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-07 143 24 -37.5003 -102.9994 2.9 18.8374 33.9534 2.64 0.43 0.20 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-08 145 20 -38.4995 -103.0006 225.6 7.4185 34.227 20.85 1.55 BDL 3 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-08 145 21 -38.4995 -103.0006 145.5 9.0549 34.1804 17.56 1.33 0.03 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-08 145 22 -38.4995 -103.0006 71.3 11.529 33.9873 9.34 0.87 BDL 3 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-08 145 23 -38.4995 -103.0006 30.9 15.8802 33.9127 8.20 0.79 0.09 2 North Pacific ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-09 149 20 -40.5001 -103.0003 172.1 8.5181 34.1873 18.21 1.33 0.34 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-09 149 22 -40.5001 -103.0003 52.2 12.693 34.0367 6.82 0.67 0.30 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-09 149 24 -40.5001 -103.0003 8.6 16.2253 33.9452 6.85 0.67 0.21 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-10 151 20 -41.5007 -103.0005 205.8 7.5491 34.2388 19.84 1.45 0.06 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-10 151 22 -41.5007 -103.0005 70 10.7446 34.0185 11.06 0.94 0.17 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-10 151 23 -41.5007 -103.0005 30 13.7916 33.9767 10.25 0.90 0.21 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-10 151 24 -41.5007 -103.0005 5.3 14.2351 33.9676 9.54 0.86 0.12 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-10 153 20 -42.5009 -102.9977 194.7 7.1421 34.2336 19.31 1.48 0.13 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-10 153 21 -42.5009 -102.9977 125.3 8.3639 34.0768 14.25 1.22 0.26 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-10 153 22 -42.5009 -102.9977 45.5 11.842 33.9728 10.44 0.98 0.13 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-10 153 23 -42.5009 -102.9977 24.6 13.1766 33.971 10.29 0.98 0.09 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-10 153 24 -42.5009 -102.9977 3.2 13.1895 33.9691 10.29 0.99 0.16 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-11 155 20 -43.5005 -102.9995 169.7 6.9912 34.2069 19.53 1.47 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-11 155 21 -43.5005 -102.9995 104.8 8.4569 34.0794 14.21 1.16 0.20 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-11 155 22 -43.5005 -102.9995 51.2 11.2917 34.0108 11.77 1.01 0.04 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-11 155 23 -43.5005 -102.9995 20.3 12.3059 33.9854 11.82 1.01 0.11 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-11 155 24 -43.5005 -102.9995 4.2 12.3045 33.9836 11.51 1.00 0.15 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-11 157 20 -44.5003 -103.0004 190.9 7.0992 34.2426 19.94 1.45 0.03 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-11 157 21 -44.5003 -103.0004 124.4 8.3276 34.1011 14.83 1.17 0.13 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-11 157 22 -44.5003 -103.0004 65.5 10.2845 34.0401 13.10 1.06 0.18 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-11 157 23 -44.5003 -103.0004 40.3 11.7586 34.0229 12.39 1.00 0.21 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-11 157 24 -44.5003 -103.0004 3.2 12.2531 34.0278 12.41 0.99 0.08 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-12 159 19 -45.5 -102.9993 249.2 6.8325 34.304 19.94 1.48 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-12 159 20 -45.5 -102.9993 179.6 7.0328 34.2481 19.43 1.47 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-12 159 21 -45.5 -102.9993 115 8.0006 34.1169 14.43 1.20 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-12 159 22 -45.5 -102.9993 59.7 10.6084 34.0602 12.39 1.05 0.25 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-12 159 23 -45.5 -102.9993 25.5 11.5795 34.0409 11.69 1.00 0.05 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-12 159 24 -45.5 -102.9993 3.3 11.614 34.0492 11.69 1.02 0.04 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-12 161 19 -46.5001 -103 234.8 6.5873 34.2707 20.87 1.53 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-12 161 20 -46.5001 -103 164.7 6.9143 34.2297 19.97 1.47 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-12 161 21 -46.5001 -103 100.3 8.1363 34.128 15.01 1.17 0.07 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-12 161 22 -46.5001 -103 53.6 10.4926 34.0996 13.52 1.11 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-12 161 23 -46.5001 -103 24.8 10.7767 34.1039 13.53 1.10 0.18 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-13 165 20 -48.5003 -102.999 197.8 6.7629 34.2558 19.22 1.43 0.07 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-13 165 21 -48.5003 -102.999 124.7 7.1061 34.1613 15.99 1.29 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-13 165 22 -48.5003 -102.999 59.4 8.5077 34.1339 14.06 1.17 0.09 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-13 165 23 -48.5003 -102.999 25.8 10.0193 34.1322 13.16 1.10 0.10 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-13 165 24 -48.5003 -102.999 4.5 10.1405 34.1289 13.17 1.09 0.06 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-16 173 20 -52.4998 -102.9998 199.2 6.452 34.2093 18.92 1.35 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-16 173 21 -52.4998 -102.9998 120.5 6.7412 34.2002 17.48 1.31 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-16 173 22 -52.4998 -102.9998 50.7 8.1152 34.1688 15.27 1.11 0.12 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-16 173 23 -52.4998 -102.9998 18.6 8.423 34.1684 14.96 1.08 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-16 173 24 -52.4998 -102.9998 9 8.4226 34.1696 14.85 1.06 0.10 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-16 175 20 -53.4998 -103.0004 231.2 6.2453 34.2141 20.05 1.43 0.11 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-16 175 21 -53.4998 -103.0004 154.6 6.3988 34.2082 19.26 1.37 0.13 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-16 175 22 -53.4998 -103.0004 68.2 7.6009 34.184 16.12 1.20 0.06 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-16 175 23 -53.4998 -103.0004 30.6 7.9553 34.1805 15.57 1.14 0.08 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-16 175 24 -53.4998 -103.0004 4.8 7.9917 34.1793 15.47 1.10 0.10 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-17 177 20 -54.4999 -102.9999 210.1 6.2673 34.2209 20.16 1.43 0.07 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-17 177 21 -54.4999 -102.9999 130.1 6.3853 34.1941 19.20 1.37 0.04 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-17 177 22 -54.4999 -102.9999 60.3 7.8538 34.1818 15.87 1.14 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-17 177 24 -54.4999 -102.9999 6.5 8.064 34.1692 15.67 1.11 0.10 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-17 179 20 -55.5005 -103.0007 200 6.2638 34.2302 20.57 1.44 0.05 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-17 179 21 -55.5005 -103.0007 117.5 6.511 34.2284 19.58 1.39 0.06 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-17 179 22 -55.5005 -103.0007 54.8 7.644 34.1807 16.27 1.17 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-17 179 23 -55.5005 -103.0007 19.9 7.7448 34.1701 16.17 1.17 0.03 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-17 179 24 -55.5005 -103.0007 3.2 7.762 34.1706 16.18 1.22 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-18 181 20 -56.5 -102.9997 247.5 5.7846 34.2477 22.34 1.57 0.11 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-18 181 21 -56.5 -102.9997 171.1 5.9309 34.2244 21.32 1.50 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-18 181 22 -56.5 -102.9997 85.8 6.2313 34.2273 20.28 1.44 0.11 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-18 181 23 -56.5 -102.9997 40 6.9295 34.2181 17.50 1.28 0.03 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-18 181 24 -56.5 -102.9997 8.5 7.0832 34.1792 17.59 1.24 0.09 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-19 183 20 -57.5005 -102.9978 194.9 5.166 34.1903 23.91 1.68 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-19 183 21 -57.5005 -102.9978 125.4 5.5953 34.2194 22.84 1.61 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-19 183 22 -57.5005 -102.9978 61.6 6.5608 34.1435 19.20 1.36 0.05 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-19 183 23 -57.5005 -102.9978 26 6.8778 34.16 18.18 1.29 0.13 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-19 183 24 -57.5005 -102.9978 3.9 6.8751 34.1579 18.39 1.29 0.13 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-19 185 20 -58.5017 -102.9976 201.6 5.0897 34.1763 23.55 1.59 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-19 185 21 -58.5017 -102.9976 120.2 5.3749 34.1781 22.10 1.52 0.09 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-22 193 21 -62.5025 -102.9984 177.7 1.0996 34.0552 30.73 2.11 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-22 193 22 -62.5025 -102.9984 51.9 1.6682 33.9737 25.18 1.84 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-22 193 23 -62.5025 -102.9984 30 3.1958 33.8748 24.38 1.62 0.04 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-23 197 20 -64.5006 -103.0002 210 1.0263 34.0649 31.46 2.18 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-23 197 21 -64.5006 -103.0002 124.6 0.6001 33.9298 29.20 2.02 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-23 197 22 -64.5006 -103.0002 54.4 2.1469 33.8656 25.67 1.81 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-23 197 23 -64.5006 -103.0002 20.1 2.939 33.8599 25.40 1.73 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-23 197 24 -64.5006 -103.0002 3.7 2.9446 33.8587 25.40 1.74 0.05 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-24 201 21 -66.5003 -103.0006 150.9 -0.3679 34.0151 31.27 2.16 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-24 201 22 -66.5003 -103.0006 70.3 -1.1761 33.7463 26.70 1.99 0.27 2 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-24 201 23 -66.5003 -103.0006 23.9 1.5814 33.6508 22.42 1.44 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-24 201 24 -66.5003 -103.0006 3.3 1.6604 33.661 22.43 1.40 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-25 205 20 -68.5001 -103.0001 234.9 1.9266 34.5877 35.67 2.40 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-25 205 21 -68.5001 -103.0001 155.2 1.1383 34.3974 35.37 2.40 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-25 205 22 -68.5001 -103.0001 70.8 -1.4684 33.9645 29.90 2.05 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-25 205 23 -68.5001 -103.0001 30.3 1.0002 33.5902 27.13 1.83 BDL 3 Southern Ocean ash/hydrolysis this study 33RO20161119 GO-SHIP P18-2016 2017-01-25 205 24 -68.5001 -103.0001 3.5 1.1458 33.4541 26.86 1.81 BDL 3 Southern Ocean ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-06 9 28 -30.0795 153.9994 316.8 13.8034 34.9416 11.90 0.86 0.13 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-06 9 29 -30.0795 153.9994 266.8 15.3522 35.1725 9.83 0.71 0.06 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-06 9 30 -30.0795 153.9994 216.6 16.7929 35.3041 7.73 0.58 0.06 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-06 9 31 -30.0795 153.9994 166.2 18.1374 35.4436 6.41 0.50 0.07 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-06 9 32 -30.0795 153.9994 116.1 19.3246 35.5506 4.05 0.34 0.10 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-06 9 34 -30.0795 153.9994 61.1 20.8322 35.6907 0.43 0.11 0.16 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-06 9 35 -30.0795 153.9994 34.6 21.3238 35.7505 0.25 0.09 0.16 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-06 9 36 -30.0795 153.9994 5.4 21.3231 35.7562 0.15 0.09 0.15 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-07 14 25 -30.0803 155.9901 504.7 11.9138 34.941 15.57 1.09 0.02 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-07 14 26 -30.0803 155.9901 402.6 14.1856 35.2168 11.21 0.80 0.07 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-07 14 27 -30.0803 155.9901 350.9 15.816 35.3248 9.46 0.68 0.09 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-07 14 28 -30.0803 155.9901 300.3 17.0459 35.4519 7.73 0.58 0.05 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-07 14 29 -30.0803 155.9901 250.3 18.4982 35.6007 5.53 0.42 0.09 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-07 14 30 -30.0803 155.9901 201 19.5691 35.6715 4.56 0.37 0.10 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-07 14 31 -30.0803 155.9901 149.1 20.228 35.7223 3.78 0.31 0.11 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-07 14 32 -30.0803 155.9901 100.3 21.2385 35.7586 2.59 0.24 0.10 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-07 14 33 -30.0803 155.9901 73.7 21.9316 35.7554 2.34 0.22 0.12 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-07 14 34 -30.0803 155.9901 50.9 22.4954 35.7314 0.07 0.06 0.24 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-07 14 35 -30.0803 155.9901 22.9 22.5322 35.7329 0.01 0.04 0.17 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-07 14 36 -30.0803 155.9901 2.8 22.528 35.7325 0.01 0.05 0.09 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-09 23 20 -30.0803 158.0001 352.5 15.9024 35.3914 8.49 0.62 0.61 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-09 23 21 -30.0803 158.0001 303 16.9191 35.4987 6.89 0.51 0.22 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-09 23 22 -30.0803 158.0001 251.7 18.2756 35.6287 4.91 0.39 0.17 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-09 23 23 -30.0803 158.0001 226.2 18.7818 35.6739 4.09 0.34 0.08 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-09 23 24 -30.0803 158.0001 202.2 19.0454 35.6838 3.87 0.32 0.16 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-09 23 25 -30.0803 158.0001 176 19.5428 35.7165 3.36 0.28 0.22 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-09 23 26 -30.0803 158.0001 151.1 20.2155 35.7876 1.30 0.15 0.24 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-09 23 27 -30.0803 158.0001 125.6 20.2508 35.8003 0.79 0.10 0.19 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-09 23 28 -30.0803 158.0001 100.8 20.2494 35.7981 0.83 0.12 0.19 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-09 23 29 -30.0803 158.0001 74.7 20.2481 35.7997 0.85 0.12 0.27 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-09 23 30 -30.0803 158.0001 49.9 20.2508 35.7993 0.83 0.13 0.16 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-09 23 31 -30.0803 158.0001 25 20.2486 35.8007 0.80 0.13 0.22 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-09 23 32 -30.0803 158.0001 4.2 20.2516 35.8011 0.80 0.14 0.17 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-10 29 16 -30.0805 160.0008 352.9 14.7625 35.3234 9.45 0.65 0.05 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-10 29 17 -30.0805 160.0008 302.3 16.0735 35.4628 7.67 0.56 0.13 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-10 29 18 -30.0805 160.0008 251.5 17.1442 35.5316 5.82 0.42 0.06 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-10 29 19 -30.0805 160.0008 201.3 18.1409 35.6214 4.32 0.34 0.10 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-10 29 20 -30.0805 160.0008 176.5 18.8277 35.6802 3.53 0.27 0.21 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-10 29 21 -30.0805 160.0008 150.7 19.2898 35.71 3.08 0.25 0.18 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-10 29 22 -30.0805 160.0008 124.9 20.1194 35.8143 1.20 0.13 0.09 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-10 29 23 -30.0805 160.0008 100.7 20.6399 35.8657 0.26 0.05 0.18 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-10 29 24 -30.0805 160.0008 75.2 20.6336 35.8669 0.24 0.05 0.18 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-10 29 25 -30.0805 160.0008 49.7 20.6297 35.8661 0.24 0.07 0.19 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-10 29 26 -30.0805 160.0008 24.6 20.6262 35.8692 0.25 0.06 0.17 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-10 29 27 -30.0805 160.0008 5.1 20.6383 35.8667 0.24 0.06 0.23 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-11 33 12 -30.0801 162.0001 318.6 15.992 35.4261 7.89 0.58 0.08 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-11 33 13 -30.0801 162.0001 267.5 17.3822 35.5294 6.50 0.49 0.07 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-11 33 14 -30.0801 162.0001 238 18.0886 35.6038 5.20 0.41 0.09 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-11 33 15 -30.0801 162.0001 212.4 18.6886 35.6822 3.60 0.31 0.16 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-11 33 16 -30.0801 162.0001 187.5 19.2156 35.7679 1.61 0.17 0.12 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-11 33 17 -30.0801 162.0001 165.5 19.418 35.7912 1.26 0.16 0.21 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-11 33 18 -30.0801 162.0001 137.4 19.6875 35.8111 0.89 0.12 0.15 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-11 33 19 -30.0801 162.0001 111.9 19.8393 35.8086 0.75 0.12 0.13 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-11 33 21 -30.0801 162.0001 62 19.9759 35.8354 0.53 0.10 0.10 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-11 33 22 -30.0801 162.0001 36.2 20.3479 35.8503 0.27 0.08 0.12 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-11 33 23 -30.0801 162.0001 5.8 20.3384 35.851 0.27 0.09 0.07 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-13 44 23 -30.0797 166.0686 352 15.7648 35.4387 7.02 0.53 0.02 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-13 44 24 -30.0797 166.0686 300.6 17.0387 35.5377 5.69 0.44 0.14 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-13 44 25 -30.0797 166.0686 250 18.0688 35.6212 4.91 0.39 0.10 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-13 44 26 -30.0797 166.0686 226.3 18.5783 35.6409 4.61 0.36 0.07 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-13 44 27 -30.0797 166.0686 198.9 19.6935 35.696 3.40 0.30 0.09 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-13 44 28 -30.0797 166.0686 174.5 19.8684 35.8264 0.64 0.10 0.11 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-13 44 29 -30.0797 166.0686 151.6 19.8641 35.8345 0.47 0.09 0.12 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-13 44 30 -30.0797 166.0686 125.1 19.8609 35.835 0.47 0.09 0.13 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-13 44 31 -30.0797 166.0686 100.3 19.8507 35.8366 0.49 0.10 0.11 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-13 44 32 -30.0797 166.0686 75.9 19.8493 35.8348 0.47 0.10 0.09 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-13 44 33 -30.0797 166.0686 48.9 19.841 35.8354 0.48 0.09 0.11 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-13 44 34 -30.0797 166.0686 24 19.8422 35.8354 0.47 0.11 0.12 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-13 44 35 -30.0797 166.0686 4.3 19.8329 35.8358 0.48 0.11 0.08 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-15 56 24 -30.08 170 352.7 15.1439 35.3366 8.51 0.63 0.16 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-15 56 26 -30.08 170 251.8 17.1178 35.5182 5.86 0.44 0.11 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-15 56 28 -30.08 170 202.2 18.8714 35.7053 3.18 0.27 0.04 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-15 56 30 -30.08 170 152.4 19.5766 35.8916 0.71 0.12 0.18 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-15 56 32 -30.08 170 102.3 19.6019 35.8672 0.69 0.10 0.20 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-15 56 33 -30.08 170 76.6 19.6047 35.8674 0.69 0.12 0.15 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-15 56 34 -30.08 170 50.6 19.5985 35.8663 0.70 0.11 0.21 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-15 56 35 -30.08 170 23.7 19.5936 35.8665 0.71 0.12 0.11 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-15 56 36 -30.08 170 4 19.5878 35.8671 0.71 0.12 0.17 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-17 64 27 -30.0798 171.9994 216.2 16.9063 35.5016 6.43 0.47 0.19 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-17 64 29 -30.0798 171.9994 166.1 17.6752 35.5882 5.14 0.38 0.19 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-17 64 31 -30.0798 171.9994 116.6 18.7642 35.7752 1.24 0.15 0.19 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-17 64 33 -30.0798 171.9994 65 19.0128 35.8038 1.10 0.13 0.13 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-17 64 34 -30.0798 171.9994 41.3 19.0755 35.8139 1.07 0.13 0.18 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-17 64 36 -30.0798 171.9994 5.5 19.0913 35.8147 1.05 0.14 0.01 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-19 75 26 -30.0803 175.9992 387.9 11.6961 35.0189 13.91 0.97 0.07 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-19 75 27 -30.0803 175.9992 337.5 13.0373 35.1599 11.14 0.79 0.07 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-19 75 28 -30.0803 175.9992 285.9 13.8559 35.2385 10.11 0.73 0.09 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-19 75 30 -30.0803 175.9992 185.4 16.0298 35.4484 6.56 0.49 0.21 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-19 75 31 -30.0803 175.9992 135.2 17.0901 35.5316 5.28 0.41 0.14 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-19 75 32 -30.0803 175.9992 89.7 18.6523 35.7736 0.57 0.10 0.11 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-19 75 33 -30.0803 175.9992 64.7 18.6756 35.7756 0.64 0.10 0.23 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-19 75 34 -30.0803 175.9992 41.1 18.7184 35.7742 0.56 0.11 0.20 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-19 75 35 -30.0803 175.9992 19.2 18.7154 35.7734 0.53 0.10 0.10 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-25 85 23 -32.4998 179.922 367.3 12.1028 35.0031 12.44 0.89 0.07 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-25 85 24 -32.4998 179.922 317.7 12.8608 35.1252 10.82 0.78 0.05 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-25 85 26 -32.4998 179.922 236.3 14.6072 35.326 8.06 0.61 0.06 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-25 85 27 -32.4998 179.922 212.8 15.0631 35.3516 7.71 0.58 0.08 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-25 85 28 -32.4998 179.922 186.4 15.7319 35.4251 6.61 0.50 0.07 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-25 85 29 -32.4998 179.922 161.5 16.0937 35.4746 5.80 0.44 0.10 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-25 85 30 -32.4998 179.922 135 17.4942 35.625 2.49 0.24 0.21 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-25 85 31 -32.4998 179.922 110.1 17.7306 35.6784 1.21 0.15 0.23 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-25 85 32 -32.4998 179.922 85.5 17.7353 35.681 1.18 0.15 0.30 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-25 85 33 -32.4998 179.922 59.1 17.7367 35.6812 1.20 0.15 0.14 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-25 85 34 -32.4998 179.922 34.7 17.7305 35.6822 1.18 0.16 0.15 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-25 85 35 -32.4998 179.922 4.1 17.7274 35.6678 1.19 0.17 0.17 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-28 97 30 -32.5 -175.75 215.5 15.2335 35.3514 6.86 0.51 0.17 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-28 97 32 -32.5 -175.75 116 17.3517 35.6317 0.95 0.13 0.21 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-28 97 33 -32.5 -175.75 84.3 17.4113 35.6445 0.80 0.13 0.20 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-28 97 34 -32.5 -175.75 61 17.6982 35.6688 0.79 0.12 0.19 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-28 97 35 -32.5 -175.75 34.1 17.7923 35.6932 0.45 0.10 0.18 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-28 97 36 -32.5 -175.75 2.9 17.8034 35.6956 0.43 0.11 0.15 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-31 106 28 -32.4994 -171.9197 266.4 14.2105 35.1725 7.81 0.63 0.17 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-31 106 30 -32.4994 -171.9197 166.5 16.7183 35.4973 3.41 0.33 0.16 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-31 106 32 -32.4994 -171.9197 110.4 17.5513 35.6915 0.36 0.10 0.18 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-07-31 106 34 -32.4994 -171.9197 59.9 17.5459 35.6909 0.36 0.11 0.13 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-02 115 28 -32.5003 -167.7931 316.9 12.6258 34.9355 11.12 0.82 0.07 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-05 121 27 -32.5001 -163.8247 366.9 9.7066 34.55 18.14 1.21 0.02 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-05 121 29 -32.5001 -163.8247 264.7 12.422 35.0618 9.47 0.65 0.05 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-05 121 30 -32.5001 -163.8247 216.7 14.0519 35.2343 6.39 0.44 0.11 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-05 121 31 -32.5001 -163.8247 167.2 15.2612 35.3642 4.72 0.34 0.07 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-05 121 32 -32.5001 -163.8247 113.8 17.0931 35.5294 1.44 0.12 0.17 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-05 121 33 -32.5001 -163.8247 84.4 17.4137 35.609 0.11 0.03 0.13 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-05 121 34 -32.5001 -163.8247 59.4 17.4166 35.6096 0.11 0.04 0.13 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-05 121 35 -32.5001 -163.8247 33.6 17.4149 35.6098 0.10 0.05 0.08 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-05 121 36 -32.5001 -163.8247 7.7 17.4098 35.61 0.11 0.06 0.03 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-06 124 27 -32.4994 -161.8331 367.3 10.7323 34.8131 12.98 0.93 0.09 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-06 124 29 -32.4994 -161.8331 267.6 13.9016 35.2101 6.99 0.54 0.06 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-06 124 30 -32.4994 -161.8331 215.5 15.0483 35.2865 4.07 0.35 0.15 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-06 124 32 -32.4994 -161.8331 116.3 17.8796 35.6328 0.13 0.06 0.21 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-06 124 34 -32.4994 -161.8331 60.7 17.9079 35.6354 0.13 0.06 0.21 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-06 124 36 -32.4994 -161.8331 6.9 17.9007 35.6323 0.13 0.08 0.19 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-09 129 28 -32.4998 -158.2078 301.2 13.481 35.0169 8.81 0.69 0.03 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-09 129 30 -32.4998 -158.2078 200.3 15.7967 35.3535 3.44 0.32 0.07 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-09 129 32 -32.4998 -158.2078 101.7 17.6408 35.5841 0.12 0.07 0.13 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-09 129 34 -32.4998 -158.2078 49.7 17.6605 35.5908 0.13 0.09 0.15 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-09 129 36 -32.4998 -158.2078 9.1 17.6455 35.5841 0.13 0.10 0.15 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-11 135 26 -32.4997 -154.2684 400.8 8.7487 34.5019 17.68 1.25 0.09 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-11 135 28 -32.4997 -154.2684 299.9 11.4673 34.76 12.71 0.93 0.08 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-11 135 30 -32.4997 -154.2684 202.1 14.2051 35.1465 5.87 0.48 0.09 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-11 135 32 -32.4997 -154.2684 102 16.8576 35.4997 0.17 0.09 0.15 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-11 135 34 -32.4997 -154.2684 51.3 16.8494 35.4949 0.18 0.10 0.20 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-11 135 36 -32.4997 -154.2684 3.9 16.8528 35.4985 0.20 0.11 0.13 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-12 141 28 -32.5 -150.2485 302.2 11.3065 34.7646 12.12 0.88 0.10 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-12 141 30 -32.5 -150.2485 200.5 14.9962 35.216 4.07 0.35 0.17 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-12 141 32 -32.5 -150.2485 98.7 16.7472 35.4862 0.20 0.09 0.19 2 South Pacific ash/hydrolysis this study 320620170703 GO-SHIP P06-2017 2017-08-12 141 36 -32.5 -150.2485 2.4 16.7347 35.4872 0.19 0.11 0.21 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-08-26 148 24 -32.5008 -145.7093 436.8 8.0855 34.4304 19.13 1.36 0.07 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-08-26 148 26 -32.5008 -145.7093 264.3 12.3975 34.8627 9.60 0.75 0.10 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-08-26 148 28 -32.5008 -145.7093 165.9 14.7688 35.179 3.57 0.35 0.14 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-08-26 148 32 -32.5008 -145.7093 85.6 16.6495 35.3417 0.05 0.10 0.16 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-08-26 148 33 -32.5008 -145.7093 59.5 16.6048 35.335 0.05 0.11 0.16 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-08-26 148 36 -32.5008 -145.7093 3.7 16.5556 35.3311 0.05 0.12 0.16 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-08-28 152 24 -32.5051 -142.2516 368.1 8.6266 34.4679 17.41 1.23 0.07 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-08-28 152 26 -32.5051 -142.2516 236.3 12.2811 34.8228 7.66 0.62 0.10 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-08-28 152 31 -32.5051 -142.2516 87.3 16.413 35.1727 -0.01 0.09 0.18 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-08-28 152 34 -32.5051 -142.2516 38.8 16.3881 35.1339 -0.01 0.09 0.18 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-08-28 152 36 -32.5051 -142.2516 5.1 16.3978 35.1169 -0.01 0.10 0.19 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-08-31 159 28 -32.5002 -135.9181 252.5 12.6449 34.7567 9.61 0.72 0.21 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-08-31 159 30 -32.5002 -135.9181 151.1 15.402 35.1634 0.53 0.12 0.29 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-08-31 159 32 -32.5002 -135.9181 102.4 16.5593 35.1786 0.00 0.07 0.34 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-08-31 159 34 -32.5002 -135.9181 51.5 17.0327 35.2808 0.00 0.07 0.29 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-08-31 159 35 -32.5002 -135.9181 25.5 17.1688 35.2873 0.00 0.07 0.27 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-08-31 159 36 -32.5002 -135.9181 10.5 17.1711 35.2836 0.00 0.09 0.22 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-03 163 28 -32.5 -132.3581 266.3 12.6589 34.7938 7.35 0.60 0.23 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-03 163 30 -32.5 -132.3581 165.3 16.2545 35.0817 0.11 0.09 0.31 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-03 163 32 -32.5 -132.3581 111.8 16.4385 35.059 0.04 0.09 0.34 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-03 163 34 -32.5 -132.3581 35.6 16.619 35.0943 0.00 0.09 0.30 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-03 163 36 -32.5 -132.3581 4.4 16.6384 35.0961 0.00 0.10 0.31 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-04 168 25 -32.5003 -127.9686 252.5 12.415 34.672 7.09 0.60 0.27 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-04 168 27 -32.5003 -127.9686 150.3 15.8428 35.0614 0.60 0.14 0.33 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-04 168 31 -32.5003 -127.9686 99.7 17.3886 35.2723 -0.03 0.07 0.35 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-04 168 32 -32.5003 -127.9686 74.5 17.2016 35.127 -0.03 0.06 0.39 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-04 168 35 -32.5003 -127.9686 23.4 17.2308 35.1713 -0.02 0.07 0.36 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-04 168 36 -32.5003 -127.9686 4.5 17.3462 35.2613 -0.02 0.09 0.33 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-09 184 24 -32.4995 -115.5757 265.5 12.3597 34.6476 8.45 0.66 0.18 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-09 184 25 -32.4995 -115.5757 214.8 13.9731 34.7744 4.92 0.43 0.26 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-09 184 27 -32.4995 -115.5757 160 15.5839 34.8456 0.93 0.21 0.30 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-09 184 31 -32.4995 -115.5757 108.9 16.7463 34.8381 0.00 0.09 0.34 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-09 184 34 -32.4995 -115.5757 58.4 17.6783 35.0216 0.00 0.08 0.32 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-09 184 35 -32.4995 -115.5757 33.9 18.4146 35.1892 0.00 0.08 0.32 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-09 184 36 -32.4995 -115.5757 8.9 18.457 35.1955 0.00 0.08 0.38 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-11 189 25 -32.5006 -111.7047 199.5 14.3803 34.7512 3.51 0.33 0.25 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-11 189 27 -32.5006 -111.7047 149.7 15.8991 34.8928 0.15 0.10 0.27 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-11 189 29 -32.5006 -111.7047 99 17.3983 34.9549 0.00 0.06 0.30 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-11 189 31 -32.5006 -111.7047 49.2 18.3792 35.1219 0.00 0.06 0.32 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-11 189 32 -32.5006 -111.7047 6.6 18.3789 35.1252 0.00 0.06 0.34 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-12 195 28 -32.4998 -107.5659 200.6 13.2474 34.5007 7.12 0.57 0.24 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-12 195 30 -32.4998 -107.5659 151.3 14.6001 34.6095 2.49 0.30 0.24 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-12 195 32 -32.4998 -107.5659 101.7 16.8956 34.7066 0.05 0.09 0.26 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-12 195 34 -32.4998 -107.5659 50.5 16.9234 34.7005 0.01 0.10 0.25 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-14 201 24 -32.5001 -103.426 302 9.9194 34.244 17.83 1.27 0.38 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-14 201 26 -32.5001 -103.426 200.6 14.1066 34.525 4.33 0.43 0.30 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-14 201 27 -32.5001 -103.426 149.9 16.5698 34.6417 0.61 0.19 0.28 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-14 201 33 -32.5001 -103.426 48.7 16.6363 34.7856 0.05 0.13 0.25 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-14 201 36 -32.5001 -103.426 6 16.645 34.7879 0.04 0.15 0.29 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-16 207 24 -32.5003 -98.8856 301.1 9.982 34.2683 16.61 1.20 0.12 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-16 207 25 -32.5003 -98.8856 250.5 12.4022 34.4803 10.42 0.80 0.14 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-16 207 26 -32.5003 -98.8856 200.3 14.2124 34.595 4.28 0.43 0.14 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-16 207 27 -32.5003 -98.8856 149.8 16.6478 34.8617 0.27 0.16 0.22 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-16 207 36 -32.5003 -98.8856 11.4 16.7518 34.888 0.08 0.16 0.28 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-18 213 25 -32.4998 -93.544 251.1 10.5609 34.2228 13.55 1.18 0.10 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-18 213 26 -32.4998 -93.544 200.1 12.7745 34.2491 8.89 0.90 0.12 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-18 213 33 -32.4998 -93.544 49.2 14.9794 34.4412 0.17 0.31 0.21 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-20 219 24 -32.4999 -88.2049 301.2 8.5015 34.2454 23.04 1.71 0.08 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-20 219 25 -32.4999 -88.2049 251.1 9.8961 34.2238 18.15 1.32 0.12 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-20 219 27 -32.4999 -88.2049 149.3 13.9809 34.2589 5.27 0.52 0.21 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-20 219 29 -32.4999 -88.2049 100.2 14.8044 34.4129 2.16 0.32 0.24 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-20 219 36 -32.4999 -88.2049 3.2 14.9943 34.4408 2.02 0.32 0.20 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-22 225 24 -32.4996 -82.8657 327.2 8.7743 34.4473 32.15 2.61 0.02 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-22 225 25 -32.4996 -82.8657 250.9 9.9329 34.4275 26.62 2.44 0.06 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-22 225 26 -32.4996 -82.8657 202 10.2292 34.2222 22.72 1.90 0.08 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-22 225 27 -32.4996 -82.8657 151.4 11.5133 34.0952 18.20 1.44 0.11 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-22 225 29 -32.4996 -82.8657 100.4 14.0075 34.2881 3.74 0.49 0.15 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-22 225 36 -32.4996 -82.8657 2.9 14.3958 34.3395 2.58 0.45 0.22 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-24 231 27 -32.5002 -77.5253 152.8 12.1038 34.0709 14.87 1.17 0.09 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-24 231 28 -32.5002 -77.5253 126.7 14.646 34.3743 2.27 0.43 0.14 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-24 231 29 -32.5002 -77.5253 100.6 14.6608 34.3755 2.22 0.43 0.19 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-24 231 32 -32.5002 -77.5253 74.2 14.6647 34.3778 2.21 0.42 0.13 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-24 231 30 -32.5002 -77.5253 74.2 14.6647 nd nd nd 0.13 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-24 231 33 -32.5002 -77.5253 49.7 14.6818 34.3802 2.19 0.44 0.10 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-24 231 35 -32.5002 -77.5253 25.6 14.6928 34.379 2.19 0.44 0.10 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-24 231 36 -32.5002 -77.5253 5.7 14.7317 34.3798 2.18 0.46 0.09 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-25 233 28 -32.4997 -75.7455 113.6 14.1116 34.264 3.21 0.51 0.11 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-25 233 29 -32.4997 -75.7455 89.7 14.2507 34.3223 2.73 0.50 0.12 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-25 233 30 -32.4997 -75.7455 74.9 14.282 34.325 2.71 0.49 0.12 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-25 233 33 -32.4997 -75.7455 39.9 14.3635 34.3305 2.68 0.49 0.17 2 South Pacific ash/hydrolysis this study 320620170820 GO-SHIP P06-2017 2017-09-25 233 34 -32.4997 -75.7455 25 14.3626 34.3364 2.65 0.50 0.12 2 South Pacific ash/hydrolysis this study 316N20071116 CoFeMUG 2007-11-18 1 4 -10.9998 -29.998 200 nd nd 12.38 0.94 0.05 2 South Atlantic ash/hydrolysis this study 316N20071116 CoFeMUG 2007-11-18 1 8 -10.9998 -29.998 135 nd nd 1.35 0.37 0.12 2 South Atlantic ash/hydrolysis this study 316N20071116 CoFeMUG 2007-11-18 1 15 -10.9998 -29.998 70 nd nd 0.18 0.11 0.16 2 South Atlantic ash/hydrolysis this study 316N20071116 CoFeMUG 2007-11-20 1 22 -10.9998 -29.998 10 nd nd 0.14 0.14 0.16 2 South Atlantic ash/hydrolysis this study 316N20071116 CoFeMUG 2007-11-20 3 6 -11.4972 -25.0078 150 nd nd 9.73 0.78 0.07 2 South Atlantic ash/hydrolysis this study 316N20071116 CoFeMUG 2007-11-20 3 13 -11.4972 -25.0078 70 nd nd 0.29 0.16 0.20 2 South Atlantic ash/hydrolysis this study 316N20071116 CoFeMUG 2007-11-23 3 21 -11.4972 -25.0078 10 nd nd 0.26 0.14 0.07 2 South Atlantic ash/hydrolysis this study 316N20071116 CoFeMUG 2007-11-23 6 6 -12.25 -17.5 150 nd nd 10.16 0.79 0.08 2 South Atlantic ash/hydrolysis this study 316N20071116 CoFeMUG 2007-11-23 6 14 -12.25 -17.5 70 nd nd 0.16 0.17 0.13 2 South Atlantic ash/hydrolysis this study 316N20071116 CoFeMUG 2007-11-24 6 22 -12.25 -17.5 10 nd nd 0.12 0.16 0.08 2 South Atlantic ash/hydrolysis this study 316N20071116 CoFeMUG 2007-11-24 11 6 -12.49483333 -4.998666667 150 nd nd 27.35 1.62 0.24 2 South Atlantic ash/hydrolysis this study 316N20071116 CoFeMUG 2007-11-24 11 14 -12.49483333 -4.998666667 70 nd nd 4.23 0.45 0.11 2 South Atlantic ash/hydrolysis this study 316N20071116 CoFeMUG 2007-11-24 11 16 -12.49483333 -4.998666667 40 nd nd 0.15 0.18 0.13 2 South Atlantic ash/hydrolysis this study 316N20071116 CoFeMUG 2007-11-30 11 22 -12.49483333 -4.998666667 10 nd nd 0.04 0.22 0.03 2 South Atlantic ash/hydrolysis this study 316N20071116 CoFeMUG 2007-12-05 13 22 -13.47416667 -0.045333333 10 nd nd 0.16 0.24 0.09 2 South Atlantic ash/hydrolysis this study 316N20071116 CoFeMUG nd 19 5 -14.7505 12.2 70 nd nd 25.77 1.65 0.21 2 South Atlantic ash/hydrolysis this study 316N20071116 CoFeMUG nd 19 9 -14.7505 12.2 40 nd nd 24.38 1.62 0.10 2 South Atlantic ash/hydrolysis this study 316N20071116 CoFeMUG nd 22 10 -24.00183333 13.50633333 50 nd nd 13.34 0.98 0.12 2 South Atlantic ash/hydrolysis this study 316N20071116 CoFeMUG nd 22 15 -24.00183333 13.50633333 30 nd nd 12.88 0.92 0.08 2 South Atlantic ash/hydrolysis this study 316N20071116 CoFeMUG nd 22 21 -24.00183333 13.50633333 10 nd nd 6.02 0.56 0.39 2 South Atlantic ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-05 stn3A nd 17.3794 -162.4426 50 nd nd 0.00 0.12 0.30 2 North Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-05 stn3B nd 17.3794 -162.4426 50 nd nd 0.00 0.12 0.30 2 North Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-05 stn3A nd 17.3794 -162.4426 75 nd nd 0.00 0.11 0.27 2 North Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-05 stn3B nd 17.3794 -162.4426 75 nd nd 0.00 0.11 0.27 2 North Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-05 stn3A nd 17.3794 -162.4426 100 nd nd 0.00 0.12 0.30 2 North Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-05 stn3B nd 17.3794 -162.4426 100 nd nd 0.00 0.12 0.30 2 North Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-05 stn3A nd 17.3794 -162.4426 130 nd nd 0.00 0.07 0.23 2 North Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-05 stn3B nd 17.3794 -162.4426 130 nd nd 0.00 0.07 0.23 2 North Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-05 stn3A nd 17.3794 -162.4426 150 nd nd 1.19 0.11 0.24 2 North Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-05 stn3B nd 17.3794 -162.4426 150 nd nd 1.19 0.11 0.24 2 North Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-05 stn3A nd 17.3794 -162.4426 200 nd nd 2.88 0.27 0.21 2 North Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-05 stn3B nd 17.3794 -162.4426 200 nd nd 2.88 0.27 0.21 2 North Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-05 stn3A nd 17.3794 -162.4426 271 nd nd 12.70 1.03 0.19 2 North Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-12 stn10A nd 0.3653 -179.644 25 nd nd 1.07 0.26 0.32 2 North Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-12 stn10B nd 0.3653 -179.644 25 nd nd 1.07 0.26 0.32 2 North Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-12 stn10A nd 0.3653 -179.644 50 nd nd 1.23 0.22 0.36 2 North Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-12 stn10B nd 0.3653 -179.644 50 nd nd 1.23 0.22 0.36 2 North Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-12 stn10A nd 0.3653 -179.644 75 nd nd 1.79 0.28 0.37 2 North Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-12 stn10B nd 0.3653 -179.644 75 nd nd 1.79 0.28 0.37 2 North Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-12 stn10A nd 0.3653 -179.644 100 nd nd 9.83 0.74 0.35 2 North Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-12 stn10B nd 0.3653 -179.644 100 nd nd 9.83 0.74 0.35 2 North Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-12 stn10A nd 0.3653 -179.644 150 nd nd 3.52 0.40 0.37 2 North Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-12 stn10B nd 0.3653 -179.644 150 nd nd 3.52 0.40 0.37 2 North Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-12 stn10A nd 0.3653 -179.644 300 nd nd 26.95 1.92 0.51 2 North Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-12 stn10B nd 0.3653 -179.644 500 nd nd 27.20 2.03 0.44 2 North Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-31 stn24A nd -36.1654 161.7915 15 nd nd 0.00 0.07 0.28 2 South Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-31 stn24B nd -36.1654 161.7915 15 nd nd 0.00 0.07 0.28 2 South Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-31 stn24A nd -36.1654 161.7915 25 nd nd 0.00 0.06 0.22 2 South Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-31 stn24B nd -36.1654 161.7915 25 nd nd 0.00 0.06 0.22 2 South Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-31 stn24A nd -36.1654 161.7915 50 nd nd 0.13 0.08 0.25 2 South Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-31 stn24B nd -36.1654 161.7915 50 nd nd 0.13 0.08 0.25 2 South Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-31 stn24A nd -36.1654 161.7915 75 nd nd 0.92 0.20 0.21 2 South Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-31 stn24B nd -36.1654 161.7915 75 nd nd 0.92 0.20 0.21 2 South Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-31 stn24A nd -36.1654 161.7915 100 nd nd 3.61 0.36 0.20 2 South Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-31 stn24B nd -36.1654 161.7915 100 nd nd 3.61 0.36 0.20 2 South Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-31 stn24A nd -36.1654 161.7915 150 nd nd 5.14 0.46 0.26 2 South Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-31 stn24B nd -36.1654 161.7915 150 nd nd 5.14 0.46 0.26 2 South Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-31 stn24A nd -36.1654 161.7915 250 nd nd 6.40 0.53 0.18 2 South Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-31 stn24B nd -36.1654 161.7915 250 nd nd 6.40 0.53 0.18 2 South Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-31 stn24A nd -36.1654 161.7915 300 nd nd 6.74 0.60 0.19 2 South Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-31 stn24B nd -36.1654 161.7915 400 nd nd 7.65 0.71 0.14 2 South Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-01-31 stn24A nd -36.1654 161.7915 500 nd nd 12.82 0.99 0.18 2 South Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-02-08 stn30 nd -28.763 155.3701 5 nd nd 0.00 0.05 0.22 2 South Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-02-08 stn30 nd -28.763 155.3701 30 nd nd 0.00 0.05 0.23 2 South Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-02-08 stn30 nd -28.763 155.3701 50 nd nd 0.00 0.05 0.21 2 South Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-02-08 stn30 nd -28.763 155.3701 75 nd nd 0.00 0.10 0.23 2 South Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-02-08 stn30 nd -28.763 155.3701 100 nd nd 3.71 0.28 0.37 2 South Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-02-08 stn30 nd -28.763 155.3701 150 nd nd 2.66 0.22 0.30 2 South Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-02-08 stn30 nd -28.763 155.3701 300 nd nd 5.64 0.42 0.30 2 South Pacific ash/hydrolysis this study 33KB20070103 WebbPacific2007 2007-02-08 stn30 nd -28.763 155.3701 500 nd nd 12.74 0.92 0.29 2 South Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-06 3 24 49.28 -134.67 4.2 16.269 32.4162 3.89 0.73 0.19 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-06 3 16 49.28 -134.67 50.4 8.0686 32.5406 10.59 1.16 0.20 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-06 3 12 49.28 -134.67 98.6 6.4753 32.5864 16.89 1.36 0.11 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-06 3 11 49.28 -134.67 200.6 5.7796 33.794 28.97 2.06 0.05 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-08 5 20 49.8003 -141.7996 3.6 15.1596 32.3704 6.85 0.93 0.15 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-08 5 17 49.8003 -141.7996 48.4 6.9623 32.5863 13.00 1.29 0.09 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-08 5 13 49.8003 -141.7996 204.5 4.4935 33.7001 31.78 2.36 0.05 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-09 8 14 52.95 -141.5458 48.8 5.9746 32.6537 15.65 1.40 0.11 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-10 10 24 54.5999 -141.4055 4.2 14.1766 32.5185 8.97 1.06 0.21 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-10 10 20 54.5999 -141.4055 49.6 5.8259 32.6456 18.43 1.53 0.07 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-10 10 17 54.5999 -141.4055 100.7 4.9585 32.769 21.33 1.64 0.06 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-12 15 22 58.9995 -140.9996 3.7 15.3697 31.4783 0.08 0.25 0.23 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-12 15 20 58.9995 -140.9996 49.5 6.4759 32.301 20.54 1.48 0.19 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-12 15 6 58.9995 -140.9996 99.4 5.9241 32.6149 20.53 1.53 0.16 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-12 15 4 58.9995 -140.9996 149.5 5.9863 33.176 27.83 2.00 0.19 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-14 17 21 57.1536 -148.7132 99.6 4.928 33.078 25.16 1.84 0.13 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-14 17 24 57.1536 -148.7132 4.8 13.186 32.5014 5.10 0.84 0.31 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-14 17 2 57.1536 -148.7132 51 5.4797 32.67 19.40 1.41 0.12 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-15 20 23 55 -152.66 3.9 12.6607 32.3454 2.83 0.72 0.15 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-15 20 14 55 -152.66 48 4.7768 32.8615 22.85 1.70 0.55 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-16 24 20 53 -152.002 5.3 12.1693 32.4839 0.13 1.05 0.26 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-16 24 13 53 -152.002 60.6 4.2427 32.9218 0.05 1.77 0.16 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-17 26 23 52.0001 -152 55.3 5.4477 32.6602 19.29 1.58 0.03 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-17 26 22 52.0001 -152 104 4.0288 32.9101 24.73 1.84 0.13 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-18 28 24 50.4491 -148.7467 3.3 13.9488 32.4451 7.14 1.03 0.18 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-18 28 23 50.4491 -148.7467 49.9 7.4058 32.5936 11.93 1.30 0.15 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-18 28 22 50.4491 -148.7467 97.5 4.379 32.7769 22.50 1.58 0.15 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-18 27 21 51 -152 3.9 12.7433 32.4616 10.24 1.14 0.21 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-18 27 15 51 -152 98.6 4.2625 32.7536 22.62 1.59 0.23 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-19 29 19 50 -145 49.8 6.8627 32.5691 13.82 1.37 0.17 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-20 30 23 49.8997 -143.3999 4.5 14.824 32.3997 5.56 0.86 0.50 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-20 30 22 49.8997 -143.3999 52.5 6.4102 32.6043 14.77 1.22 0.23 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-20 30 21 49.8997 -143.3999 103.2 5.4477 32.6422 19.50 1.54 0.05 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-21 32 24 49.4271 -136.6661 4.6 16.2453 32.3704 2.16 0.64 0.18 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-21 32 23 49.4271 -136.6661 50.1 8.911 32.4206 7.16 1.10 0.23 2 North Pacific ash/hydrolysis this study 318M20130804 Gulf of Alaska 2013 2013-08-21 32 22 49.4271 -136.6661 99.8 6.7999 32.6572 15.87 1.30 0.17 2 North Pacific ash/hydrolysis this study 33AT20100129 ETSP2010 2010-02-01 1 24 -20 -80 0 20.5672 35.2043 0.04 0.50 0.13 2 South Pacific ash/hydrolysis this study 33AT20100129 ETSP2010 2010-02-01 1 23 -20 -80 20 20.5477 35.1992 0.05 0.40 0.23 2 South Pacific ash/hydrolysis this study 33AT20100129 ETSP2010 2010-02-01 1 22 -20 -80 40 18.5166 34.934 0.05 0.39 0.22 2 South Pacific ash/hydrolysis this study 33AT20100129 ETSP2010 2010-02-01 1 21 -20 -80 60 16.8223 34.7462 2.29 0.48 0.23 2 South Pacific ash/hydrolysis this study 33AT20100129 ETSP2010 2010-02-01 1 20 -20 -80 80 16.5496 34.8167 4.03 0.71 0.10 2 South Pacific ash/hydrolysis this study 33AT20100129 ETSP2010 2010-02-01 1 19 -20 -80 100 15.1241 34.5921 6.71 0.77 0.16 2 South Pacific ash/hydrolysis this study 33AT20100129 ETSP2010 2010-02-03 1 18 -20 -80 120 12.3109 34.2292 11.95 1.10 0.08 2 South Pacific ash/hydrolysis this study 33AT20100129 ETSP2010 2010-02-03 1 16 -20 -80 200 11.4277 34.6782 23.23 2.86 0.02 2 South Pacific ash/hydrolysis this study 33AT20100129 ETSP2010 2010-02-03 2 24 -20 -85 0 20.9169 35.4441 0.04 0.31 0.26 2 South Pacific ash/hydrolysis this study 33AT20100129 ETSP2010 2010-02-03 2 21 -20 -85 40 20.5183 35.3487 0.03 0.31 0.21 2 South Pacific ash/hydrolysis this study 33AT20100129 ETSP2010 2010-02-03 2 18 -20 -85 80 18.1944 35.0301 0.04 0.31 0.17 2 South Pacific ash/hydrolysis this study 33AT20100129 ETSP2010 2010-02-07 4 23 -20 -95 0 22.7423 35.7542 0.04 0.23 0.26 2 South Pacific ash/hydrolysis this study 33AT20100129 ETSP2010 2010-02-07 4 21 -20 -95 20 22.4117 35.7593 0.05 nd 0.39 2 South Pacific ash/hydrolysis this study 33AT20100129 ETSP2010 2010-02-07 4 12 -20 -95 200 16.676 34.9991 4.17 0.53 0.16 2 South Pacific ash/hydrolysis this study 33AT20100129 ETSP2010 2010-02-12 6 24 -15 -100 0 23.2698 35.8274 1.80 0.47 0.29 2 South Pacific ash/hydrolysis this study 33AT20100129 ETSP2010 2010-02-12 6 23 -15 -100 0 23.2698 35.8274 1.72 nd 0.24 2 South Pacific ash/hydrolysis this study 33AT20100129 ETSP2010 2010-02-12 6 22 -15 -100 20 22.9715 35.834 1.28 0.45 0.35 2 South Pacific ash/hydrolysis this study 33AT20100129 ETSP2010 2010-02-12 6 19 -15 -100 60 21.8532 35.841 0.24 0.37 0.31 2 South Pacific ash/hydrolysis this study 33AT20100129 ETSP2010 2010-02-12 6 15 -15 -100 100 20.7501 35.786 0.33 0.43 0.21 2 South Pacific ash/hydrolysis this study 33AT20100129 ETSP2010 2010-02-12 6 13 -15 -100 150 20.1344 35.6745 2.44 0.51 0.25 2 South Pacific ash/hydrolysis this study 33AT20100129 ETSP2010 2010-02-12 6 12 -15 -100 200 16.6946 35.0659 9.66 1.08 0.02 2 South Pacific ash/hydrolysis this study 33AT20100129 ETSP2010 2010-02-17 8 23 -10 -95 0 24.9881 35.4426 5.00 0.55 0.24 2 South Pacific ash/hydrolysis this study 33AT20100129 ETSP2010 2010-02-17 8 17 -10 -95 80 16.8425 35.1078 12.93 1.29 0.10 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-03-26 1 14 -20 -80 110 16.2323 34.7672 4.37 0.64 0.19 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-03-26 1 13 -20 -80 120 16.1911 34.7761 5.07 0.69 0.14 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-03-26 1 12 -20 -80 140 15.6868 34.6959 8.57 0.95 0.12 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-03-26 1 11 -20 -80 160 14.7366 34.5264 10.37 1.04 0.17 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-03-26 1 10 -20 -80 180 12.7697 34.4738 16.61 1.57 0.07 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-03-26 1 9 -20 -80 200 12.0218 34.5025 20.66 2.09 0.04 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-03-26 1 8 -20 -80 225 11.4915 34.5817 23.39 2.53 0.06 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-03-26 1 7 -20 -80 250 11.1452 34.6196 24.77 2.69 0.06 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-03-30 11 24 -10 -82 2 25.1877 35.2695 3.95 0.56 0.38 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-03-30 11 23 -10 -82 20 25.1487 35.261 3.82 0.58 0.38 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-03-30 11 22 -10 -82 35 25.0967 35.2475 9.58 1.21 0.37 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-03-30 11 21 -10 -82 40 20.4833 35.2125 14.00 1.49 0.26 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-03-30 11 20 -10 -82 50 18.8185 35.1988 14.65 1.53 0.30 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-03-30 11 19 -10 -82 60 17.2586 35.262 23.65 1.98 0.21 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-03-30 11 18 -10 -82 65 16.6518 35.2081 29.05 2.31 0.20 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-03-30 11 17 -10 -82 70 15.6197 35.1232 28.94 2.37 0.16 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-03-30 11 16 -10 -82 80 14.4166 35.0415 29.02 2.47 0.14 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-03-30 11 15 -10 -82 90 14.0715 35.0032 29.48 2.41 0.17 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-03-30 11 14 -10 -82 95 13.9047 34.9938 28.43 2.41 0.19 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-03-30 11 13 -10 -82 100 13.7938 34.9881 28.85 2.40 0.14 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-03-30 11 12 -10 -82 110 13.5687 34.9796 28.90 2.42 0.11 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-03-30 11 11 -10 -82 120 13.369 34.9694 29.53 2.43 0.04 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-03-30 11 10 -10 -82 150 12.973 34.9453 30.10 2.43 0.09 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-03-30 11 12 -10 -82 175 12.5579 34.9321 nd 2.45 0.08 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-03-30 11 9 -10 -82 200 12.3783 34.9135 30.71 2.44 0.14 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-03-30 11 8 -10 -82 225 12.0827 34.8942 nd 2.47 0.16 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-03-30 11 7 -10 -82 250 11.7995 34.864 31.93 2.51 0.11 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-18 13 24 -15 -82 5 22.9093 35.2732 0.37 0.55 0.40 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-18 13 23 -15 -82 20 22.9134 35.2744 0.56 0.59 0.35 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-18 13 22 -15 -82 35 22.8118 35.1072 7.78 1.00 0.22 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-18 13 21 -15 -82 40 18.9305 35.1074 8.39 1.01 0.18 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-18 13 20 -15 -82 50 16.9287 35.1436 12.06 1.31 0.20 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-18 13 19 -15 -82 60 16.5997 35.0215 14.18 1.47 0.17 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-18 13 18 -15 -82 70 15.7881 34.9083 16.33 1.64 0.18 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-18 13 17 -15 -82 80 14.9736 34.8742 18.49 1.85 0.15 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-18 13 16 -15 -82 90 14.2414 34.8564 20.99 2.12 0.15 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-18 13 15 -15 -82 100 13.7531 34.8688 24.52 2.69 0.14 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-18 13 14 -15 -82 110 13.3738 34.8859 19.37 2.84 0.17 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-18 13 13 -15 -82 120 13.1767 34.8869 17.51 2.77 0.11 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-18 13 12 -15 -82 140 12.723 34.9025 19.36 2.68 0.15 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-18 13 11 -15 -82 160 12.5018 34.9021 19.95 2.71 0.12 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-18 13 10 -15 -82 180 12.2888 34.8956 23.43 2.65 0.03 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-18 13 9 -15 -82 200 12.1262 34.886 25.04 2.65 0.09 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-18 13 8 -15 -82 225 12.0048 34.8696 27.47 2.64 0.07 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-18 13 7 -15 -82 250 11.7482 34.8509 28.28 2.66 0.19 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-10 5 24 -20 -100 5 23.3503 35.9168 0.03 0.30 0.36 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-10 5 22 -20 -100 20 23.2921 35.917 0.13 0.32 0.38 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-05 7 24 -10 -100 2 26.1734 35.3684 7.60 0.66 0.22 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-05 7 23 -10 -100 20 26.0995 35.369 7.80 0.67 0.20 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-05 7 22 -10 -100 40 24.7695 35.371 6.99 0.67 0.24 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-05 7 21 -10 -100 45 23.1566 35.6387 3.73 0.52 0.39 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-05 7 20 -10 -100 50 22.2031 35.7927 4.64 0.61 0.27 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-05 7 19 -10 -100 60 21.1762 35.6908 6.05 0.76 0.21 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-05 7 18 -10 -100 70 19.9939 35.691 7.99 0.90 0.21 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-05 7 17 -10 -100 80 19.2734 35.6343 9.93 1.01 0.15 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-05 7 16 -10 -100 90 18.1423 35.5907 11.72 1.14 0.13 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-05 7 15 -10 -100 100 17.0274 35.5304 14.83 1.37 0.15 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-05 7 14 -10 -100 110 15.9511 35.4456 17.86 1.60 0.26 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-05 7 13 -10 -100 120 14.7166 35.2318 19.82 1.83 0.21 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-05 7 12 -10 -100 160 13.2365 34.8415 nd 2.57 0.16 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-05 7 11 -10 -100 180 12.5005 34.8173 nd 2.53 0.07 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-05 7 10 -10 -100 200 11.8638 34.8109 nd 2.47 0.05 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-05 7 9 -10 -100 225 11.4267 34.8233 nd 2.43 0.09 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-05 7 8 -10 -100 250 11.0775 34.8145 nd 2.45 0.01 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-05 7 7 -10 -100 275 10.7977 34.7973 nd 2.48 0.03 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-02 9 24 -10 -90 2 26.8433 35.0795 6.39 0.60 0.23 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-02 9 22 -10 -90 30 25.2233 35.0797 8.75 0.80 0.19 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-02 9 21 -10 -90 35 20.8282 35.0876 13.75 1.18 0.24 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-02 9 20 -10 -90 40 20.1773 35.2869 14.56 1.22 0.20 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-02 9 19 -10 -90 50 18.8 35.3222 20.01 1.77 0.12 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-02 9 18 -10 -90 60 16.0969 35.1482 26.46 2.24 0.22 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-02 9 17 -10 -90 65 15.6519 35.0413 26.47 2.35 0.06 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-02 9 16 -10 -90 70 15.4207 35.0087 25.78 2.41 0.15 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-02 9 15 -10 -90 80 14.2957 34.9862 25.79 2.45 0.08 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-02 9 14 -10 -90 90 14.0212 34.9732 25.63 2.45 0.13 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-02 9 13 -10 -90 100 13.6865 34.9597 27.97 2.45 0.21 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-02 9 13 -10 -90 110 13.4278 34.9521 27.30 2.45 0.08 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-02 9 12 -10 -90 125 13.0378 34.9352 29.16 2.45 0.10 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-02 9 11 -10 -90 150 12.5795 34.9138 30.19 2.38 0.16 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-02 9 10 -10 -90 175 12.1555 34.9002 30.45 2.37 0.04 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-02 9 9 -10 -90 200 11.8909 34.881 32.24 2.38 0.04 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-02 9 8 -10 -90 225 11.6979 34.8618 32.74 2.38 0.06 2 South Pacific ash/hydrolysis this study 318M20110323 ETSP2011 2011-04-02 9 7 -10 -90 250 11.4617 34.8441 32.03 2.47 0.09 2 South Pacific ash/hydrolysis this study nd SCALE 2019-10-12 1 nd -34.641 17.425 5 19.35 35.22 0.61 0.10 0.29 2 South Atlantic ash/hydrolysis this study nd SCALE 2019-10-13 6 nd -35.607 15.285 5 19.8 35.25 0.99 0.01 0.38 2 South Atlantic ash/hydrolysis this study nd SCALE 2019-10-13 12 nd -36.481 13.184 5 15.68 35.08 1.09 0.36 0.09 2 South Atlantic ash/hydrolysis this study nd SCALE 2019-10-14 15 nd -37.596 12.46 5 15.15 35.14 2.07 0.38 0.02 2 South Atlantic ash/hydrolysis this study nd SCALE 2019-10-14 19 nd -39.004 11.512 5 12.33 34.66 5.54 0.47 0.13 2 South Atlantic ash/hydrolysis this study nd SCALE 2019-10-15 28 nd -41.591 9.63 5 11.46 34.32 7.52 0.85 0.21 2 Southern Ocean ash/hydrolysis this study nd SCALE 2019-10-15 36 nd -42.575 8.831 5 8.06 34.07 15.02 0.97 0.10 2 Southern Ocean ash/hydrolysis this study nd SCALE 2019-10-16 44 nd -44.777 6.817 5 5.67 33.77 19.93 1.18 0.03 2 Southern Ocean ash/hydrolysis this study nd SCALE 2019-10-17 49 nd -46.902 5.304 5 5.04 33.61 18.93 1.37 0.07 2 Southern Ocean ash/hydrolysis this study nd SCALE 2019-10-17 54.5 nd -48.489 4.184 5 3.83 33.61 21.23 1.42 0.24 2 Southern Ocean ash/hydrolysis this study nd SCALE 2019-10-18 57 nd -49.474 3.468 5 2.33 33.58 24.65 1.62 0.22 2 Southern Ocean ash/hydrolysis this study nd SCALE 2019-10-18 60 nd -50.655 2.6 5 2.03 33.6 25.36 1.78 0.18 2 Southern Ocean ash/hydrolysis this study nd SCALE 2019-10-18 63 nd -51.646 1.847 5 1.14 33.65 26.39 1.70 0.15 2 Southern Ocean ash/hydrolysis this study nd SCALE 2019-10-18 65 nd -52.277 1.362 5 0.58 33.66 26.70 1.86 0.29 2 Southern Ocean ash/hydrolysis this study nd SCALE 2019-10-19 68 nd -53.307 0.572 5 -0.05 33.65 26.81 1.85 0.12 2 Southern Ocean ash/hydrolysis this study nd SCALE 2019-10-19 71 nd -54.383 0 5 -0.8 33.68 26.60 2.16 0.16 2 Southern Ocean ash/hydrolysis this study nd SCALE 2019-10-22 111 nd -55.995 0.022 5 -1.61 33.83 28.29 2.23 0.33 2 Southern Ocean ash/hydrolysis this study nd GOM2019 2019-04-09 19towfish1 nd 27.79234 -82.9179 1 23.50745 34.0873 0.00 0.10 0.40 2 North Atlantic ash/hydrolysis this study nd GOM2019 2019-04-09 19towfish2 nd 28.17038 -82.9226 1 23.6135 32.855 0.00 0.05 0.22 2 North Atlantic ash/hydrolysis this study nd GOM2019 2019-04-10 19towfish3 nd 27.3833 -82.715 1 23.71135 34.9625 0.18 0.00 0.36 2 North Atlantic ash/hydrolysis this study nd GOM2019 2019-04-10 19towfish4 nd 27.3667 -82.9 1 23.2801 35.5562 0.00 0.00 0.25 2 North Atlantic ash/hydrolysis this study nd GOM2019 2019-04-10 19towfish5 nd 27.3575 -83.18722 1 23.2349 35.9227 0.00 0.00 0.25 2 North Atlantic ash/hydrolysis this study nd GOM2019 2019-04-10 19towfish6 nd 27.28762 -83.58218 1 23.70525 36.3937 0.00 0.00 0.19 2 North Atlantic ash/hydrolysis this study nd GOM2019 2019-04-11 19towfish7 nd 27.15006 -85.14278 1 25.1766 36.4772 0.00 0.00 0.13 2 North Atlantic ash/hydrolysis this study nd GOM2019 2019-04-11 19towfish8 nd 27.4 -84.9044 1 23.0783 36.2678 0.00 0.00 0.15 2 North Atlantic ash/hydrolysis this study nd GOM2019 2019-04-11 19towfish9 nd 27.59006 -84.75576 1 23.77495 36.4099 0.00 0.00 0.21 2 North Atlantic ash/hydrolysis this study nd GOM2019 2019-04-11 19towfish10 nd 27.70722 -84.553056 1 23.95225 36.3924 0.00 0.00 0.20 2 North Atlantic ash/hydrolysis this study nd GOM2019 2019-04-12 19towfish11 nd 27.826944 -83.93833 1 23.3254 36.3023 0.00 0.00 0.22 2 North Atlantic ash/hydrolysis this study nd GOM2019 2019-04-12 19towfish12 nd 27.85 -83.65 1 23.13125 36.2309 0.00 0.00 0.20 2 North Atlantic ash/hydrolysis this study nd GOM2019 2019-04-12 19towfish13 nd 27.8166 -83.0166 1 24.46755 34.9407 0.00 0.00 0.24 2 North Atlantic ash/hydrolysis this study nd GOM2019 2019-04-12 19towfish14 nd 27.7 -82.9 1 25.11995 34.8902 0.00 0.06 0.25 2 North Atlantic ash/hydrolysis this study nd GOM2019 2019-04-12 19towfish15 nd 27.58944 -82.86306 1 24.81385 35.1601 0.00 0.00 0.23 2 North Atlantic ash/hydrolysis this study nd SWINGS 2021-01-13 U1 nd -22.183417 53.96145 5 26.783 35.474 nd 0.09 0.16 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-01-14 U2 nd -22.96435 53.1442 5 26.861 35.282 nd 0.11 0.13 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-01-14 U4 nd -23.944267 52.1178333 5 nd nd nd 0.11 0.43 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-01-14 U5 nd -24.5514 51.4745167 5 27.106 35.355 nd 0.08 0.32 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-01-16 U8 nd -26.0474 47.86685 5 27.821 35.044 nd 0.11 0.26 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-01-16 U9 nd -26.5853 46.2394667 5 27.119 35.182 nd 0.14 0.07 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-01-16 U10 nd -27.0376 44.87305 5 26.862 35.271 nd 0.14 0.35 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-01-16 U11 nd -27.2843 44.1298167 5 26.93 35.417 nd 0.14 0.25 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-01-17 U12 nd -27.811867 42.5138 5 29.067 35.271 nd 0.08 0.29 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-01-17 U13 nd -28.341367 40.8955833 5 27.639 35.585 nd 0.05 0.19 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-01-18 U14 nd -28.7795 39.3930667 5 26.568 35.48 nd 0.08 0.12 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-01-18 U15 nd -29.178217 37.6620833 5 26.698 35.48 nd 0.05 0.19 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-01-18 U16 nd -29.5405 36.1028 5 26.778 35.4 nd 0.04 0.34 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-01-18 U17 nd -29.897233 34.5554333 5 26.951 35.529 nd 0.07 0.28 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-01-20 U18 nd -30.219283 32.4886167 5 27.703 27.612 nd 0.05 0.26 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-01-23 U19 nd -37.11255 36.0133167 5 21.933 35.593 nd 0.05 0.14 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-03-03 U20 nd -41.783567 66.0010333 5 16.922 35.215 nd 0.23 0.29 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-03-03 U21 nd -39.368567 64.7121167 5 17.224 34.992 nd 0.24 0.31 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-03-03 U22 nd -37.475433 63.6418 5 19.185 35.327 nd 0.16 0.30 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-03-04 U23 nd -35.0028 62 5 21.849 35.455 nd 0.45 0.26 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-03-04 U24 nd -33.162 61.02445 5 23.815 35.769 nd 0.14 0.19 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-03-05 U25 nd -30.562833 59.7019333 5 24.521 34.419 nd 0.09 0.21 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-03-05 U26 nd -28.9728 58.8814 5 25.71 35.839 nd 0.16 0.18 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-03-05 U27 nd -27.698633 58.2488 5 26.89 35.404 nd 0.07 0.30 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-01-14 1 21 -24.99981667 51.00003333 5 nd nd nd 0.03 0.32 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-01-17 2 24 -28.6375 39.98733333 15 nd nd nd 0.02 0.30 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-01-17 2 21 -28.6375 39.98733333 50 nd nd nd 0.04 0.33 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-01-17 2 20 -28.6375 39.98733333 75 nd nd nd 0.06 0.28 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-01-19 3 24 -30.29996667 32.80005 5 nd nd nd 0.03 0.29 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-01-19 3 21 -30.29996667 32.80005 30 nd nd nd 0.02 0.22 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-01-19 3 20 -30.29996667 32.80005 80 nd nd nd 0.03 0.24 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-01-20 4 UW -29.80991667 31.69603333 5 nd nd nd 0.04 0.28 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-01-20 4 20 -29.80991667 31.69603333 11 nd nd nd 0.03 0.33 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-01-21 5 UW -30.1178 31.78498333 5 nd nd nd 0.04 0.39 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-01-21 5 20 -30.1178 31.78498333 15 nd nd nd 0.03 0.28 2 Indian Ocean ash/hydrolysis this study nd SWINGS 2021-01-21 5 11 -30.1178 31.78498333 50 nd nd nd 0.03 0.25 2 Indian Ocean ash/hydrolysis this study