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#  DOP concentration observations from the global ocean between 1990 and 2021 
#  PI: Angela Knapp
#  Co-PI: Robert Letscher
#  Contact: Zhou Liang
#  Data Version 1: 2021-10-05
=========================
EXPOCODE                        cruise           date        StationID  BottleID  LATITUDE       LONGITUDE      depth    Temperature  Salinity    NO3_plus_NO2  PO4         DOP         region           method           reference                                                               
-------------------------
nd                              BIOSOPE          2004-10-28  21         21        -8.325450      -141.275210    5.6      27.793   35.56       1.54          0.39        0.21        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        -8.325450      -141.275210    15.1     27.773   35.559      1.54          0.42        0.18        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        -8.325450      -141.275210    20.8     27.764   35.559      1.54          0.42        0.19        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        -8.325450      -141.275210    30.6     27.755   35.558      1.59          0.41        0.21        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        -8.325450      -141.275210    40.2     27.745   35.558      1.59          0.41        0.21        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        -8.325450      -141.275210    49.7     27.742   35.558      1.64          0.41        0.22        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        -8.995820      -136.847790    5.3      27.76    35.615      1.49          0.29        0.29        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        -8.995820      -136.847790    20.4     27.715   35.614      1.59          0.30        0.27        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        -8.995820      -136.847790    29.7     27.709   35.616      1.54          0.29        0.29        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        -8.995820      -136.847790    40.2     27.671   35.621      1.59          0.31        0.27        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        -8.995820      -136.847790    60.5     27.577   35.627      1.64          0.32        0.28        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         -8.995820      -136.847790    80.4     27.293   35.719      1.54          0.37        0.24        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        -11.735280     -134.096330    9.8      27.805   35.833      nd            0.31        0.24        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        -11.735280     -134.096330    24       27.696   35.975      0.05          0.26        0.30        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        -11.735280     -134.096330    39.2     27.559   36.001      0.09          0.22        0.34        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        -11.735280     -134.096330    49.3     27.503   36.003      0.09          0.22        0.31        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        -11.735280     -134.096330    69.9     27.424   36.016      0.14          0.23        0.30        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         -11.735280     -134.096330    91.7     26.864   36.435      nd            0.25        0.29        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        -13.553330     -132.106860    15.485   27.501   36.135      0.00          0.21        0.29        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        -13.553330     -132.106860    30.076   26.847   36.344      0.00          0.21        0.28        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        -13.553330     -132.106860    40.937   26.738   36.381      0.00          0.22        0.26        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        -13.553330     -132.106860    59.685   26.23    36.581      0.00          0.22        0.25        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        -13.553330     -132.106860    80.657   25.818   36.582      0.00          0.22        0.23        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         -13.553330     -132.106860    99.957   25.417   36.551      0.00          0.24        0.18        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        -15.534300     -129.927540    14.9     27.068   36.338      0.05          0.19        0.27        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        -15.534300     -129.927540    35.3     26.87    36.33       0.05          0.20        0.25        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        -15.534300     -129.927540    45.1     26.593   36.383      0.09          0.21        0.23        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        -15.534300     -129.927540    65.1     26.437   36.496      0.05          0.20        0.23        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        -15.534300     -129.927540    84.2     26.069   36.552      0.05          0.18        0.21        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         -15.534300     -129.927540    108.5    25.459   36.551      0.05          0.20        0.19        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        -17.234470     -127.971760    20.2     26.487   36.533      0.00          0.21        0.22        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        -17.234470     -127.971760    40.1     26.114   36.566      0.00          0.22        0.20        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        -17.234470     -127.971760    60.2     25.991   36.574      0.00          0.24        0.18        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        -17.234470     -127.971760    79.7     25.887   36.574      0.00          0.19        0.22        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         -17.234470     -127.971760    105.2    25.413   36.576      0.00          0.20        0.20        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         -17.234470     -127.971760    141.6    24.592   36.474      0.10          0.19        0.36        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        -18.747170     -125.551510    19.2     25.657   36.531      0.00          0.16        0.27        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        -18.747170     -125.551510    39.2     25.372   36.582      0.00          0.17        0.26        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        -18.747170     -125.551510    54.8     25.275   36.584      0.00          0.15        0.26        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        -18.747170     -125.551510    79.8     24.634   36.541      0.00          0.15        0.24        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         -18.747170     -125.551510    104.8    24.002   36.432      0.00          0.19        0.19        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         -18.747170     -125.551510    132.7    22.513   36.157      0.44          0.22        0.18        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        -20.454670     -122.893050    25.1     24.519   36.386      0.00          0.14        0.19        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        -20.454670     -122.893050    55.6     24.33    36.391      0.00          0.15        0.22        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        -20.454670     -122.893050    74.6     24.325   36.398      0.05          0.16        0.21        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        -20.454670     -122.893050    84.7     24.321   36.402      nd            0.15        0.20        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         -20.454670     -122.893050    124.8    23.511   36.267      0.00          0.14        0.20        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         -20.454670     -122.893050    149.9    22.815   36.142      nd            0.15        0.19        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        -22.050070     -120.382050    19.8     24.277   36.4        0.05          0.14        0.20        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        -22.050070     -120.382050    40.6     24.227   36.432      0.05          0.14        0.20        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        -22.050070     -120.382050    59.3     24.077   36.399      0.00          0.15        0.20        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        -22.050070     -120.382050    79.7     23.145   36.198      0.00          0.13        0.19        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         -22.050070     -120.382050    109.6    22.418   36.069      0.00          0.12        0.18        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         -22.050070     -120.382050    140.3    21.738   35.943      0.00          0.13        0.15        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        -23.553720     -117.889250    30.8     23.385   36.318      0.00          0.13        0.17        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        -23.553720     -117.889250    59.6     23.042   36.314      0.00          0.15        0.15        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        -23.553720     -117.889250    81       22.4     36.137      0.00          0.13        0.16        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         -23.553720     -117.889250    139.3    22.094   36.172      0.00          0.22        0.08        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         -23.553720     -117.889250    178.7    20.57    35.816      0.15          0.19        0.11        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        -25.969750     -114.005050    29.7     22.079   36.029      0.00          0.13        0.13        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        -25.969750     -114.005050    41       22.079   36.031      nd            0.12        0.15        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        -25.969750     -114.005050    69.3     21.892   36.062      0.00          0.12        0.14        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        -25.969750     -114.005050    89.5     21.596   36.009      0.00          0.13        0.13        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        -25.969750     -114.005050    120.1    20.754   35.848      0.00          0.12        0.17        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         -25.969750     -114.005050    187.1    19.103   35.515      0.15          0.19        0.30        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        -27.772750     -107.286230    29       21.283   35.923      0.00          0.12        0.13        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        -27.772750     -107.286230    62.1     21.179   35.957      0.00          0.14        0.11        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        -27.772750     -107.286230    90.5     20.832   35.945      0.05          0.13        0.14        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        -27.772750     -107.286230    120.9    20.428   35.857      0.00          0.14        0.13        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         -27.772750     -107.286230    199.4    19.223   35.548      0.07          0.16        0.11        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        -28.536270     -104.308000    105.7    20.023   35.761      0.00          0.13        0.12        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        -28.536270     -104.308000    140.9    19.556   35.647      0.00          0.13        0.12        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         -28.536270     -104.308000    183      18.103   35.258      0.10          0.14        0.10        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        -29.225200     -101.480980    25.1     19.985   35.478      0.00          0.12        0.15        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        -29.225200     -101.480980    50.5     19.219   35.461      0.00          0.12        0.15        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        -29.225200     -101.480980    64.8     18.982   35.436      0.00          0.12        0.16        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        -29.225200     -101.480980    88.9     18.536   35.365      0.00          0.12        0.16        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        -29.225200     -101.480980    120.6    18.378   35.371      0.00          0.13        0.14        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         -29.225200     -101.480980    159.4    17.286   35.167      1.31          0.23        0.12        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        -30.042000     -98.392280     19.8     19.768   35.457      0.05          0.14        0.13        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        -30.042000     -98.392280     45.3     18.677   35.341      0.00          0.13        0.14        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        -30.042000     -98.392280     59.3     18.881   35.458      0.00          0.13        0.15        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        -30.042000     -98.392280     85.1     18.74    35.462      0.00          0.13        0.14        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        -30.042000     -98.392280     110      18.61    35.444      0.00          0.13        0.14        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         -30.042000     -98.392280     149.7    18.378   35.395      0.05          0.15        0.15        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        -30.786380     -95.427200     15       18.02    34.858      0.00          0.15        0.17        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        -30.786380     -95.427200     34.9     18.04    34.86       0.00          0.15        0.16        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        -30.786380     -95.427200     49.7     17.609   34.828      0.00          0.15        0.17        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        -30.786380     -95.427200     69.2     17.157   34.866      0.00          0.15        0.16        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        -30.786380     -95.427200     99.7     16.951   34.894      0.15          0.16        0.16        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         -30.786380     -95.427200     119.5    16.923   34.916      0.39          0.20        0.16        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        -31.869000     -91.415180     4.8      18.2178  34.6901     nd            0.19        0.21        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        -31.869000     -91.415180     15.1     18.0481  34.6903     nd            0.22        0.19        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        -31.869000     -91.415180     29.8     17.987   34.6865     nd            0.19        0.22        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        -31.869000     -91.415180     40       17.0367  34.6049     nd            0.19        0.23        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        -31.869000     -91.415180     60.4     16.5443  34.6732     nd            0.21        0.21        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        -31.869000     -91.415180     78.2     16.2068  34.6223     nd            0.24        0.21        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         -31.869000     -91.415180     99.4     16.0308  34.6164     nd            0.31        0.21        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         -31.869000     -91.415180     110.6    15.906   34.5944     nd            0.31        0.20        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         -31.869000     -91.415180     125.1    15.6364  34.5412     nd            0.30        0.21        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         -31.869000     -91.415180     149.6    15.3149  34.4724     nd            0.36        0.16        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         -31.869000     -91.415180     189.4    14.5498  34.3375     nd            0.46        0.16        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         -31.869000     -91.415180     249.9    11.5617  34.2521     nd            1.00        0.15        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         -31.917380     -91.407220     303.7    9.96     34.2079     nd            1.30        0.10        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         -31.917380     -91.407220     401.5    7.4869   34.3241     nd            2.07        0.06        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        -31.917380     -91.407220     600.8    5.711    34.2776     nd            1.89        0.07        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        -31.917380     -91.407220     800.5    4.7847   34.2718     nd            2.16        0.07        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        -31.917380     -91.407220     1001.4   3.8903   34.364      nd            2.58        0.07        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        -31.917380     -91.407220     2001.1   2.1899   34.631      nd            2.61        0.09        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        -32.395450     -86.782420     14.8     17.3278  34.353      0.05          0.31        0.22        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        -32.395450     -86.782420     30       17.1962  34.3562     2.28          0.32        0.24        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        -32.395450     -86.782420     40.6     16.1555  34.3047     2.33          0.34        0.22        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        -32.395450     -86.782420     53.3     15.2465  34.2622     3.06          0.39        0.19        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        -32.395450     -86.782420     70.1     14.9522  34.3008     nd            0.37        0.18        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         -32.395450     -86.782420     95.5     14.7349  34.2853     2.91          0.41        0.16        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        -32.683250     -84.073700     14.7     17.4407  34.2435     3.64          0.39        0.21        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        -32.683250     -84.073700     30       16.4748  34.2111     3.08          0.35        0.23        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        -32.683250     -84.073700     40       15.4507  34.1856     3.64          0.37        0.22        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        -32.683250     -84.073700     59.7     14.8119  34.2245     3.96          0.45        0.17        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        -32.683250     -84.073700     80.2     14.5688  34.2093     4.81          0.52        0.13        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         -32.683250     -84.073700     99.3     13.9043  34.1051     6.22          0.56        0.10        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        -33.023120     -81.200490     14.2     17.2028  34.2707     2.77          0.37        0.22        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        -33.023120     -81.200490     35.4     16.578   34.2861     2.72          0.38        0.20        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        -33.023120     -81.200490     49.9     16.1802  34.2571     2.67          0.37        0.21        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        -33.023120     -81.200490     70.4     15.108   34.2019     3.30          0.38        0.22        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        -33.023120     -81.200490     90.5     14.6581  34.2009     4.32          0.48        0.19        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         -33.023120     -81.200490     116.4    14.1259  34.1446     5.97          0.56        0.15        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        -33.354000     -78.118780     4.7      17.5647  33.947      0.10          0.27        0.26        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        -33.354000     -78.118780     14.1     16.1316  33.9486     0.24          0.28        0.24        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        -33.354000     -78.118780     20.3     15.8947  33.9434     0.73          0.31        0.23        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        -33.354000     -78.118780     30       15.3185  34.0051     2.33          0.36        0.33        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        -33.354000     -78.118780     41.1     14.813   33.9936     3.30          0.43        0.25        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         -33.354000     -78.118780     50.6     13.8693  33.9535     4.61          0.58        0.16        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        -33.606130     -75.831130     5.6      16.8075  34.0462     0.07          0.36        0.28        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        -33.606130     -75.831130     14.7     16.7961  34.0458     0.07          0.36        0.28        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        -33.606130     -75.831130     20.4     16.7886  34.0448     0.07          0.36        0.26        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        -33.606130     -75.831130     29.7     16.2083  34.0331     0.05          0.35        0.52        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        -33.606130     -75.831130     39.5     15.7484  34.0473     0.14          0.36        0.31        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         -33.606130     -75.831130     50.2     15.0761  34.0504     1.63          0.53        0.22        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        -33.933200     -73.364050     5        15.9309  34.2456     0.29          0.51        0.44        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        -33.933200     -73.364050     9        15.9306  34.2456     0.29          0.57        0.42        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        -33.933200     -73.364050     15.4     15.9307  34.2457     nd            0.52        0.43        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        -33.933200     -73.364050     19.6     15.9158  34.2453     0.68          0.55        0.43        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        -33.933200     -73.364050     24.8     15.918   34.2434     nd            0.61        0.46        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         -33.933200     -73.364050     35.7     13.9263  34.2717     nd            0.67        0.38        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        -34.513670     -72.416620     4.4      nd       nd          nd            1.62        0.38        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        -34.513670     -72.416620     10       nd       nd          nd            1.72        0.37        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        -34.513670     -72.416620     15.1     nd       nd          nd            1.81        0.29        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        -34.513670     -72.416620     19.8     nd       nd          nd            1.84        0.33        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        -34.513670     -72.416620     30.2     nd       nd          nd            2.02        0.25        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         -34.513670     -72.416620     39.7     nd       nd          nd            2.11        0.24        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        -26.052630     -114.010950    5.1      22.408   36.021      0.00          0.12        0.18        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        -26.052630     -114.010950    18.4     22.292   36.028      0.00          0.13        0.16        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        -26.052630     -114.010950    50.4     22.108   36.046      0.00          0.13        0.17        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        -26.052630     -114.010950    71.3     21.906   36.022      0.00          0.12        0.17        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        -26.052630     -114.010950    89.5     21.427   35.976      0.00          0.12        0.17        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        -26.052630     -114.010950    118.8    20.76    35.845      0.00          0.13        0.16        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         -26.052630     -114.010950    140.3    20.235   35.74       0.00          0.13        0.16        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         -26.052630     -114.010950    158.9    19.711   35.634      0.00          0.17        0.13        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         -26.052630     -114.010950    181.1    18.658   35.438      0.49          0.21        0.14        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         -26.052630     -114.010950    199.5    17.851   35.312      1.75          0.29        0.12        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         -26.052630     -114.010950    228.6    16.806   35.144      3.45          0.39        0.10        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         -26.052630     -114.010950    270.7    14.858   34.858      5.78          0.55        0.27        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        -26.070650     -114.001300    302.6    13.392   34.716      nd            0.72        0.08        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        -26.070650     -114.001300    403.4    9.079    34.391      nd            1.47        0.04        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        -26.070650     -114.001300    600      6.093    34.31       nd            1.84        0.05        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        -26.070650     -114.001300    800.9    4.983    34.298      nd            2.19        0.06        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        -26.070650     -114.001300    1000.4   4.099    34.401      nd            2.57        0.07        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        -26.070650     -114.001300    2001.5   2.06     34.64       nd            2.57        0.07        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        -33.996320     -73.369610     5.2      15.7198  34.241      nd            0.56        0.36        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        -33.996320     -73.369610     10.1     15.726   34.2411     nd            0.56        0.34        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        -33.996320     -73.369610     14.8     15.7066  34.2398     nd            0.59        0.49        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        -33.996320     -73.369610     20       15.647   34.2366     nd            0.70        0.40        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        -33.996320     -73.369610     25       15.5861  34.2323     nd            0.89        0.35        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        -33.996320     -73.369610     29.9     14.2374  34.2538     nd            1.77        0.46        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        -33.996320     -73.369610     35.4     12.5     34.3388     nd            2.11        0.30        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         -33.996320     -73.369610     40.2     12.2614  34.34       nd            2.15        0.27        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         -33.996320     -73.369610     45.3     11.9656  34.3743     nd            2.33        0.28        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         -33.996320     -73.369610     49.9     11.6311  34.3525     nd            2.31        0.16        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         -33.996320     -73.369610     75.4     11.0336  34.3805     nd            2.51        0.17        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         -33.996320     -73.369610     100.7    10.8903  34.4941     nd            2.73        0.12        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        -33.860500     -73.340220     148.6    10.1481  34.5037     nd            2.66        0.23        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        -33.860500     -73.340220     200.4    9.524    34.521      nd            2.77        0.27        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         -33.860500     -73.340220     250.3    9.0263   34.5245     nd            2.86        0.20        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         -33.860500     -73.340220     301      8.3728   34.4905     nd            2.84        0.14        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         -33.860500     -73.340220     399.9    7.1448   34.4149     nd            2.41        0.28        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         -33.860500     -73.340220     503.4    6.1605   34.3557     nd            2.63        0.13        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         -17.941800     159.925500     149.612  21.1097  35.6954     3.17          0.30        0.10        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -17.941800     159.925500     124.97   21.6266  35.701      2.84          0.28        0.11        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -17.941800     159.925500     104.741  22.2953  35.6949     1.54          0.20        0.12        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -17.941800     159.925500     71.201   24.2831  35.5917     0.00          0.11        0.15        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -17.941800     159.925500     54.034   26.108   35.3997     0.02          0.08        0.14        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -17.941800     159.925500     36.026   28.1106  35.1108     0.01          0.02        0.18        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -17.941800     159.925500     24.133   28.2469  35.0871     0.00          0.06        0.19        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -17.941800     159.925500     16.624   28.3636  35.083      0.00          0.00        0.30        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -17.941800     159.925500     9.869    29.0101  35.0684     0.00          0.04        0.17        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -17.941800     159.925500     5.674    29.1668  35.0605     0.01          0.03        0.17        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.607800     162.124800     199.39   21.19    35.7321     5.38          0.47        0.08        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.607800     162.124800     150.278  22.437   35.6937     3.71          0.34        0.10        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.607800     162.124800     124.977  22.9537  35.6891     2.80          0.31        0.11        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.607800     162.124800     105.362  23.4386  35.6361     1.85          0.26        0.09        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.607800     162.124800     88.2     24.105   35.6005     0.77          0.19        0.12        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.607800     162.124800     70.228   24.8337  35.5396     0.02          0.13        0.14        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.607800     162.124800     53.239   25.6637  35.4598     0.05          0.09        0.16        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.607800     162.124800     9.532    28.8666  35.1928     0.00          0.03        0.18        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.607800     162.124800     5.156    28.7881  35.1893     0.02          0.03        0.19        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -19.495500     165.009300     150.423  23.1483  35.723      3.96          0.36        0.10        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -19.495500     165.009300     125.914  24.0126  35.6618     2.20          0.30        0.10        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -19.495500     165.009300     105.281  24.4989  35.5594     0.77          0.20        0.12        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -19.495500     165.009300     88.519   24.9601  35.5193     0.53          0.18        0.13        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -19.495500     165.009300     71.304   25.6016  35.4301     0.03          0.15        0.11        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.495500     165.009300     54.427   26.5235  35.3327     0.00          0.09        0.17        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.495500     165.009300     36.312   27.2729  35.2424     0.04          0.06        0.18        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.495500     165.009300     25.55    28.6367  34.9615     0.02          0.02        0.18        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.495500     165.009300     16.584   28.8649  34.8805     0.03          0.01        0.19        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.495500     165.009300     9.307    29.0252  34.8698     0.04          0.01        0.18        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.495500     165.009300     5.867    29.0497  34.8703     0.04          0.00        0.18        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.490700     165.008200     399.801  14.1636  35.1108     12.44         0.91        0.02        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.490700     165.008200     300.448  18.4446  35.5233     6.42          0.52        0.04        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.490700     165.008200     250.75   20.1137  35.6471     6.20          0.48        0.05        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.490700     165.008200     201.534  21.6462  35.7286     5.90          0.43        0.07        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -19.224800     164.649500     498.685  10.0638  34.7033     19.35         1.39        0.02        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -19.224800     164.649500     397.374  13.8547  35.0991     12.45         0.92        0.02        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -19.224800     164.649500     301.335  17.6994  35.4372     8.53          0.73        0.03        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -19.224800     164.649500     201.723  21.9705  35.7195     4.32          0.40        0.07        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -19.224800     164.649500     151.621  23.7621  35.6817     2.49          0.33        0.08        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -19.224800     164.649500     101.88   24.7562  35.549      0.87          0.22        0.10        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -19.224800     164.649500     88.455   25.1377  35.4966     0.60          0.18        0.12        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.224800     164.649500     70.614   25.6466  35.4305     0.11          0.13        0.15        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.224800     164.649500     53.546   26.3693  35.3512     0.00          0.10        0.17        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.224800     164.649500     35.433   28.6084  35.0282     0.01          0.02        0.19        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.224800     164.649500     24.525   28.8869  34.9671     0.04          0.02        0.17        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.224800     164.649500     9.353    29.0802  34.7613     0.02          0.00        0.20        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.224800     164.649500     5.246    29.1519  34.729      0.04          0.01        0.17        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -19.224200     164.587700     200.313  21.7826  35.76       4.95          0.47        0.06        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -19.224200     164.587700     150.328  23.1248  35.6841     3.07          0.35        0.07        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -19.224200     164.587700     125.297  23.7495  35.6472     2.32          0.30        0.08        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -19.224200     164.587700     105.935  24.1396  35.6123     1.84          0.28        0.07        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -19.224200     164.587700     88.384   24.8467  35.542      0.92          0.24        0.09        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -19.224200     164.587700     70.699   25.335   35.4755     0.02          0.18        0.10        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.224200     164.587700     54.042   25.8532  35.4102     0.00          0.17        0.10        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.224200     164.587700     35.199   26.7792  35.315      0.00          0.13        0.12        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.224200     164.587700     23.849   27.9162  35.1543     0.00          0.06        0.16        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.224200     164.587700     5.571    29.7346  34.9416     0.02          0.03        0.12        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.223300     164.578700     250.608  20.2184  35.7055     7.23          0.63        0.04        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.223300     164.578700     200.079  22.2707  35.7364     4.72          0.43        0.05        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -19.983200     168.011800     151.045  20.937   35.691      2.55          0.22        0.09        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -19.983200     168.011800     126.501  21.5116  35.6935     1.44          0.18        0.09        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -19.983200     168.011800     105.855  21.783   35.6978     1.27          0.16        0.11        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -19.983200     168.011800     88.882   22.3304  35.6987     1.15          0.15        0.11        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.983200     168.011800     53.776   24.0523  35.668      0.01          0.06        0.14        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.983200     168.011800     35.421   25.8663  35.6501     0.00          0.04        0.14        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.983200     168.011800     24.702   27.7499  35.3656     0.00          0.03        0.13        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.983200     168.011800     16.393   28.5439  35.3564     0.00          0.03        0.14        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.983200     168.011800     9.559    28.7332  35.3627     0.00          0.05        0.14        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.983200     168.011800     5.22     28.7346  35.363      0.01          0.06        0.15        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.980000     168.015700     499.394  9.3131   34.6711     20.00         1.40        0.02        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.980000     168.015700     300.722  16.0504  35.3514     8.38          0.67        0.02        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.980000     168.015700     249.251  18.3246  35.5894     4.65          0.39        0.05        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.980000     168.015700     199.244  19.7116  35.6617     3.29          0.28        0.09        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -22.000200     169.994300     201.308  19.9059  35.6543     4.08          0.33        0.13        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -22.000200     169.994300     150.638  21.0615  35.6963     2.18          0.20        0.10        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -22.000200     169.994300     105.517  21.9409  35.704      1.15          0.16        0.12        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -22.000200     169.994300     71.977   23.1991  35.6721     1.34          0.21        0.08        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -22.000200     169.994300     53.927   24.9936  35.5573     0.14          0.09        0.14        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -22.000200     169.994300     35.681   26.5018  35.4286     0.01          0.03        0.16        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -22.000200     169.994300     24.513   27.4658  35.3497     0.01          0.08        0.16        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -22.000200     169.994300     14.794   29.1201  35.041      0.01          0.03        0.14        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -22.000200     169.994300     9.231    29.5253  34.8793     0.01          0.04        0.16        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -22.000200     169.994300     4.536    29.5124  34.9081     0.00          0.04        0.14        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -21.999700     169.996500     500.478  10.7505  34.7908     17.56         1.24        0.05        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -21.999700     169.996500     400.579  13.4786  35.0155     13.58         1.03        0.07        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -21.999700     169.996500     301.476  17.2649  35.4654     6.65          0.52        0.12        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -21.999700     169.996500     250.999  18.9462  35.5835     4.93          0.41        0.07        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -21.999700     169.996500     200.413  19.981   35.6633     3.66          0.31        0.07        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -21.373200     172.119800     200.244  21.4935  35.723      3.71          0.33        0.07        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -21.373200     172.119800     150.474  22.9121  35.7016     1.92          0.22        0.10        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -21.373200     172.119800     135.713  23.4521  35.6961     0.95          0.19        0.10        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -21.373200     172.119800     119.568  23.9103  35.6763     0.25          0.14        0.12        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -21.373200     172.119800     100.854  24.3012  35.671      0.06          0.12        0.13        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -21.373200     172.119800     60.128   26.0567  35.6228     0.03          0.03        0.19        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -21.373200     172.119800     40.762   27.9061  35.3923     0.04          0.04        0.17        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -21.373200     172.119800     28.196   28.6292  35.062      0.02          0.04        0.17        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -21.373200     172.119800     18.222   29.2885  35.0298     0.03          0.03        0.19        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -21.373200     172.119800     11.144   29.5601  34.916      0.02          0.03        0.17        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -21.373200     172.119800     5.277    29.5789  34.8974     0.01          0.01        0.21        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -21.375800     172.119300     300.323  18.3841  35.5233     5.83          0.47        0.06        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -21.375800     172.119300     250.223  19.9928  35.6532     4.31          0.37        0.06        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -21.375800     172.119300     200.495  21.2807  35.7148     4.00          0.35        0.08        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -20.769700     174.250000     174.107  21.0716  35.6822     3.40          0.26        0.09        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -20.769700     174.250000     149.591  21.7706  35.6859     2.96          0.25        0.08        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -20.769700     174.250000     134.802  21.9997  35.6749     2.25          0.21        0.10        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -20.769700     174.250000     114.789  22.582   35.6722     1.80          0.19        0.13        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -20.769700     174.250000     90.043   23.4817  35.6655     0.43          0.13        0.13        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -20.769700     174.250000     69.994   24.5541  35.6398     0.09          0.10        0.13        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -20.769700     174.250000     44.595   27.1876  35.4954     0.02          0.02        0.18        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -20.769700     174.250000     32.058   27.9005  35.4931     0.02          0.02        0.17        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -20.769700     174.250000     20.85    28.1977  35.3869     0.01          0.02        0.21        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -20.769700     174.250000     12.247   29.6206  35.0084     0.02          0.04        0.18        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -20.769700     174.250000     5.579    29.9017  35.0171     0.00          0.04        0.21        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -20.996300     178.608700     300.431  16.8371  35.4182     6.93          0.55        0.04        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -20.996300     178.608700     250.549  18.5004  35.5717     4.71          0.40        0.04        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -20.996300     178.608700     200.003  19.6061  35.6521     3.58          0.30        0.05        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -20.441700     -178.510500    175.482  21.3639  35.6715     2.58          0.26        0.05        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -20.441700     -178.510500    150.782  22.0512  35.6751     2.48          0.24        0.05        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -20.441700     -178.510500    134.919  22.401   35.659      1.45          0.19        0.06        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -20.441700     -178.510500    114.486  23.0034  35.6546     0.32          0.14        0.08        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -20.441700     -178.510500    90.177   23.8338  35.6631     0.02          0.09        0.11        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -20.441700     -178.510500    69.23    24.6423  35.6497     0.03          0.09        0.12        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -20.441700     -178.510500    45.274   26.5594  35.5484     0.04          0.07        0.13        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -20.441700     -178.510500    33.108   28.0026  35.3435     0.01          0.02        0.16        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -20.441700     -178.510500    21.738   29.4012  35.2132     0.01          0.01        0.16        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -20.441700     -178.510500    12.988   29.5315  35.2097     0.01          0.01        0.16        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -20.441700     -178.510500    5.765    29.6064  35.2114     0.01          0.01        0.17        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -20.440000     -178.510500    201.656  21.0113  35.6709     3.14          0.29        0.04        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -20.002800     -175.654200    200.655  19.5649  35.61       3.54          0.33        0.06        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -20.002800     -175.654200    151.548  20.7522  35.6633     2.75          0.26        0.07        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -20.002800     -175.654200    135.72   21.3419  35.6841     2.42          0.26        0.06        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -20.002800     -175.654200    114.375  22.1146  35.6777     2.29          0.22        0.06        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -20.002800     -175.654200    90.083   22.8714  35.6798     0.05          0.14        0.08        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -20.002800     -175.654200    70.779   23.7673  35.678      0.02          0.08        0.12        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -20.002800     -175.654200    45.479   26.2259  35.5802     0.00          0.04        0.14        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -20.002800     -175.654200    32.586   27.0351  35.5117     0.01          0.02        0.16        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -20.002800     -175.654200    21.675   27.5472  35.4813     0.02          0.05        0.12        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -20.002800     -175.654200    12.071   28.8867  35.4173     0.01          0.02        0.15        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -20.002800     -175.654200    5.859    29.186   35.4111     0.02          0.02        0.15        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -20.005700     -175.647500    297.671  15.8426  35.2641     8.13          0.64        0.05        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -20.005700     -175.647500    251.052  17.9689  35.4858     5.16          0.43        0.04        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -19.523700     -172.788500    199.819  20.0378  35.6254     2.58          0.21        0.08        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -19.523700     -172.788500    176.144  20.4695  35.6191     1.79          0.21        0.06        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -19.523700     -172.788500    150.828  21.1151  35.6802     2.14          0.26        0.05        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -19.523700     -172.788500    128.237  22.0573  35.6961     2.49          0.27        0.06        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -19.523700     -172.788500    107.803  22.9046  35.7075     1.45          0.21        0.09        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -19.523700     -172.788500    84.702   24.0045  35.7257     0.01          0.13        0.10        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.523700     -172.788500    65.499   25.2848  35.7064     0.01          0.10        0.14        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.523700     -172.788500    43.298   26.9282  35.5955     0.01          0.06        0.16        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.523700     -172.788500    30.363   28.897   35.1336     0.02          0.06        0.15        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.523700     -172.788500    19.214   29.4943  34.9667     0.05          0.06        0.16        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.523700     -172.788500    10.713   29.8033  34.8934     0.00          0.08        0.16        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.523700     -172.788500    5.749    29.8378  34.8955     0.04          0.08        0.15        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.536800     -172.781300    398.84   13.0843  35.028      12.23         0.89        0.02        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.536800     -172.781300    299.852  17.1736  35.4628     4.14          0.36        0.06        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.536800     -172.781300    251.183  18.509   35.5306     4.23          0.35        0.05        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -19.536800     -172.781300    199.781  20.1418  35.6274     2.23          0.22        0.06        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.246200     -170.827500    299.423  16.5467  35.2847     7.63          0.65        0.03        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.246200     -170.827500    201.193  21.1541  35.79       3.27          0.35        0.06        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.246200     -170.827500    149.422  22.2933  35.7545     2.33          0.27        0.09        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.246200     -170.827500    69.187   25.2403  35.7155     0.10          0.11        0.14        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.246200     -170.827500    55.913   26.165   35.6565     0.05          0.11        0.16        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.246200     -170.827500    42.428   27.0212  35.5692     0.04          0.07        0.18        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.246200     -170.827500    27.399   29.2191  35.25       0.01          0.04        0.18        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.246200     -170.827500    11.932   29.9674  35.0821     0.03          0.01        0.18        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.246200     -170.827500    5.589    30.1582  35.0823     nd            0.01        0.17        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.179000     -170.743300    152.048  22.5548  35.7511     1.53          0.24        0.12        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.179000     -170.743300    125.479  23.5083  35.7499     0.56          0.14        0.15        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.179000     -170.743300    83.501   25.0636  35.7323     0.01          0.13        0.13        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.179000     -170.743300    69.165   25.7374  35.6852     0.04          0.11        0.16        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.179000     -170.743300    56.784   26.2317  35.6751     0.03          0.12        0.16        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.179000     -170.743300    41.743   27.1323  35.5734     0.02          0.08        0.16        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.179000     -170.743300    26.734   29.657   35.1263     0.02          0.04        0.16        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.179000     -170.743300    19.3     29.9321  35.052      0.00          0.02        0.17        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.179000     -170.743300    12.192   29.9305  35.052      0.00          0.02        0.17        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.179000     -170.743300    6.832    29.9301  35.0521     0.01          0.03        0.18        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.179000     -170.743300    5.536    29.9213  35.0404     0.04          0.04        0.17        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.174500     -170.738500    296.94   17.3588  35.3801     6.13          0.54        0.01        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.174500     -170.738500    249.471  19.6111  35.6375     4.72          0.44        0.04        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.174500     -170.738500    203.571  21.1383  35.8012     3.82          0.39        0.04        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.200700     -169.072800    500.745  8.3926   34.4702     23.60         1.67        0.02        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.200700     -169.072800    400.327  11.7201  34.7873     15.26         1.09        0.02        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.200700     -169.072800    300.133  16.2255  35.2339     8.14          0.69        0.05        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.200700     -169.072800    201.756  20.6276  35.7976     4.05          0.43        0.07        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.200700     -169.072800    150.41   22.5011  35.9628     2.17          0.33        0.08        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.200700     -169.072800    100.557  23.9781  35.8336     0.17          0.16        0.13        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.200700     -169.072800    75.644   25.1626  35.7859     0.01          0.16        0.14        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.200700     -169.072800    64.877   25.8702  35.7322     0.02          0.14        0.17        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.200700     -169.072800    55.238   26.5672  35.6835     0.01          0.14        0.16        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.200700     -169.072800    45.061   27.1103  35.64       0.01          0.14        0.17        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.200700     -169.072800    25.372   29.5928  35.092      0.01          0.15        0.16        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.200700     -169.072800    5.121    29.5913  35.0912     0.00          0.13        0.19        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.430700     -165.916000    300.473  16.6876  35.2856     9.31          0.84        0.01        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.430700     -165.916000    250.333  19.096   35.6115     5.33          0.54        0.03        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.430700     -165.916000    200.136  20.6863  35.7901     3.57          0.40        0.05        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.430700     -165.916000    151.482  21.9888  35.8632     2.22          0.33        0.04        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.430700     -165.916000    135.556  22.5416  35.8842     1.09          0.27        0.08        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.430700     -165.916000    120.897  22.9518  35.8358     0.03          0.19        0.13        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.430700     -165.916000    92.261   24.0959  35.7425     0.03          0.13        0.15        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.430700     -165.916000    60.245   25.8864  35.7067     0.05          0.13        0.13        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.430700     -165.916000    27.203   29.1759  35.2162     0.02          0.16        0.15        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.430700     -165.916000    6.641    29.3923  35.2119     0.02          0.28        0.15        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.428200     -165.931500    300.778  16.5252  35.2632     9.39          0.85        0.03        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.428200     -165.931500    201.358  20.441   35.7541     3.59          0.40        0.07        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.428200     -165.931500    135.785  22.5385  35.8361     0.64          0.21        0.11        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.428200     -165.931500    51.297   25.5336  35.7204     0.02          0.09        0.16        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.428200     -165.931500    30.392   27.4317  35.5138     0.02          0.10        0.18        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.428200     -165.931500    20.518   29.1495  35.24       0.01          0.14        0.19        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.428200     -165.931500    10.765   29.3295  35.2115     0.01          0.16        0.17        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.428200     -165.931500    4.536    29.33    35.2112     0.02          0.16        0.16        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.495200     -165.864700    24.93    29.0887  35.2838     nd            nd          0.30        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.495200     -165.864700    24.884   29.0861  35.2853     nd            nd          0.31        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.495200     -165.864700    24.65    29.0859  35.2851     nd            nd          0.31        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.495200     -165.864700    24.766   29.0914  35.2841     nd            nd          0.34        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.495200     -165.864700    25.007   29.1355  35.2781     nd            nd          0.32        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.495200     -165.864700    24.789   29.1446  35.2767     nd            nd          0.31        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.495200     -165.864700    24.919   29.151   35.2758     nd            nd          0.32        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.495200     -165.864700    24.715   29.1561  35.275      nd            nd          0.32        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.495200     -165.864700    24.957   29.171   35.272      nd            nd          0.33        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.495200     -165.864700    24.9     29.1723  35.2719     nd            nd          0.31        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.491200     -165.791500    297.703  17.446   35.3891     8.39          0.76        0.03        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.491200     -165.791500    249.476  19.2293  35.6368     6.43          0.57        0.04        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.491200     -165.791500    200.423  20.5635  35.79       4.02          0.44        0.03        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.491200     -165.791500    177.151  21.5321  35.8984     3.30          0.39        0.07        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.491200     -165.791500    150.217  22.3648  35.9228     1.79          0.30        0.07        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.491200     -165.791500    135.77   22.6788  35.9188     0.98          0.26        0.09        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.491200     -165.791500    119.977  22.995   35.8702     nd            nd          0.12        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.491200     -165.791500    91.416   23.9651  35.8364     0.03          0.14        0.14        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.491200     -165.791500    60.733   26.0231  35.6996     0.04          0.11        0.15        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.491200     -165.791500    42.233   27.5218  35.5054     0.04          0.11        0.17        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.491200     -165.791500    27.279   29.1138  35.2593     0.03          0.13        0.20        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.491200     -165.791500    17.216   29.1201  35.2572     0.02          0.14        0.18        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.491200     -165.791500    7.256    29.1152  35.2573     0.01          0.14        0.17        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.484200     -165.779200    400.514  12.1328  34.7933     14.94         1.12        0.03        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.484200     -165.779200    299.662  16.7745  35.2969     9.33          0.81        0.04        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.484200     -165.779200    249.952  18.976   35.6011     6.09          0.60        0.03        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.484200     -165.779200    197.741  20.8194  35.8205     3.96          0.44        0.05        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.395000     -163.001000    300.274  17.3308  35.3652     7.86          0.70        0.08        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.395000     -163.001000    249.174  19.704   35.6867     5.28          0.51        0.08        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.395000     -163.001000    199.327  21.6561  35.8918     3.30          0.39        0.12        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.395000     -163.001000    165.23   22.4648  35.8405     0.76          0.23        0.13        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.395000     -163.001000    139.975  23.4434  35.83       0.09          0.14        0.19        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.395000     -163.001000    110.896  24.8161  35.8136     0.04          0.14        0.19        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.395000     -163.001000    84.853   25.5853  35.7833     0.05          0.14        0.21        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.395000     -163.001000    55.934   27.5651  35.6242     0.01          0.14        0.23        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.395000     -163.001000    40.378   29.1064  35.0712     0.03          0.14        0.23        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.265000     -159.991300    300.275  17.9544  35.4622     7.88          0.74        0.05        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.265000     -159.991300    248.139  19.9578  35.7574     5.73          0.59        0.07        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.265000     -159.991300    198.698  22.1014  36.0304     4.16          0.47        0.10        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.265000     -159.991300    174.734  22.5011  36.0166     3.00          0.39        0.09        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.265000     -159.991300    148.103  23.5544  36.1056     2.62          0.40        0.11        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         -18.265000     -159.991300    115.952  24.3329  35.9205     0.24          0.18        0.17        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.265000     -159.991300    88.08    25.5851  35.9202     0.03          0.17        0.19        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.265000     -159.991300    57.892   27.7516  35.7116     0.02          0.16        0.21        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.265000     -159.991300    41.565   29.1439  35.2885     0.01          0.17        0.21        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.265000     -159.991300    26.44    29.2301  35.2578     0.03          0.16        0.22        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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        -18.265000     -159.991300    5.482    29.2015  35.1762     0.01          0.17        0.20        South Pacific    Wet oxidation    Moutin; T.; Wagener; T.; Caffin; M.; Fumenia; A.; Gimenez; A.; Baklouti; M.; Bouruet-Aubertot; P.; Pujo-Pay; M.; Leblanc; K.; Lefevre; D.; Helias Nunige; S.; Leblond; N.; Grosso; O.; and de Verneil; A.: Nutrient availability and the ultimate control of the biological 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         nd          0          nd        30.000000      145.000000     0        nd       nd          0.01          0.01        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          0          nd        30.000000      145.000000     50       nd       nd          0.01          0.00        0.16        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          0          nd        30.000000      145.000000     75       nd       nd          0.01          0.01        0.20        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          0          nd        30.000000      145.000000     100      nd       nd          0.24          0.05        0.20        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          0          nd        30.000000      145.000000     124      nd       nd          2.09          0.18        0.24        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          0          nd        30.000000      145.000000     150      nd       nd          3.63          0.20        0.42        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          1          nd        23.000000      155.000000     0        nd       nd          0.02          0.03        0.11        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          1          nd        23.000000      155.000000     5        nd       nd          0.01          0.00        0.15        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          1          nd        23.000000      155.000000     8        nd       nd          0.01          0.00        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          1          nd        23.000000      155.000000     29       nd       nd          0.01          0.00        0.16        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          1          nd        23.000000      155.000000     49       nd       nd          0.01          0.00        0.11        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          1          nd        23.000000      155.000000     74       nd       nd          0.01          0.00        0.10        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          1          nd        23.000000      155.000000     99       nd       nd          0.01          0.01        0.11        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          1          nd        23.000000      155.000000     124      nd       nd          0.19          0.04        0.13        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          1          nd        23.000000      155.000000     134      nd       nd          0.15          0.04        0.09        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          1          nd        23.000000      155.000000     148      nd       nd          0.05          0.00        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          2          nd        23.000000      160.000000     0        nd       nd          0.01          0.00        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          2          nd        23.000000      160.000000     6        nd       nd          0.01          0.00        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          2          nd        23.000000      160.000000     10       nd       nd          0.01          0.00        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          2          nd        23.000000      160.000000     19       nd       nd          0.01          0.00        0.24        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          2          nd        23.000000      160.000000     30       nd       nd          0.01          0.00        0.11        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          2          nd        23.000000      160.000000     51       nd       nd          0.01          0.00        0.11        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          2          nd        23.000000      160.000000     75       nd       nd          0.01          0.00        0.10        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          2          nd        23.000000      160.000000     99       nd       nd          0.01          0.02        0.11        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          2          nd        23.000000      160.000000     116      nd       nd          0.49          0.07        0.08        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          2          nd        23.000000      160.000000     149      nd       nd          1.07          0.09        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          3          nd        23.000000      165.000000     0        nd       nd          0.01          0.03        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          3          nd        23.000000      165.000000     5        nd       nd          0.01          0.03        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          3          nd        23.000000      165.000000     9        nd       nd          0.01          0.04        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          3          nd        23.000000      165.000000     19       nd       nd          0.01          0.03        0.20        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          3          nd        23.000000      165.000000     30       nd       nd          0.01          0.03        0.15        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          3          nd        23.000000      165.000000     48       nd       nd          0.01          0.03        0.15        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          3          nd        23.000000      165.000000     97       nd       nd          0.01          0.03        0.23        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          3          nd        23.000000      165.000000     119      nd       nd          0.01          0.03        0.13        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          3          nd        23.000000      165.000000     148      nd       nd          1.14          0.12        0.20        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          4          nd        23.000000      170.000000     0        nd       nd          0.01          0.01        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          4          nd        23.000000      170.000000     5        nd       nd          0.01          0.01        0.16        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          4          nd        23.000000      170.000000     10       nd       nd          0.01          0.01        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          4          nd        23.000000      170.000000     20       nd       nd          0.01          0.01        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          4          nd        23.000000      170.000000     31       nd       nd          0.01          0.01        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          4          nd        23.000000      170.000000     50       nd       nd          0.01          0.00        0.16        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          4          nd        23.000000      170.000000     74       nd       nd          0.01          0.01        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          4          nd        23.000000      170.000000     98       nd       nd          0.49          0.12        0.09        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          4          nd        23.000000      170.000000     100      nd       nd          0.46          0.11        0.05        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          4          nd        23.000000      170.000000     149      nd       nd          3.59          0.22        0.22        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          4B         nd        23.000000      174.920000     0        nd       nd          0.01          0.00        0.13        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          4B         nd        23.000000      174.920000     5        nd       nd          0.01          0.00        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          4B         nd        23.000000      174.920000     10       nd       nd          0.01          0.00        0.16        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          4B         nd        23.000000      174.920000     19       nd       nd          0.01          0.00        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          4B         nd        23.000000      174.920000     30       nd       nd          0.01          0.01        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          4B         nd        23.000000      174.920000     49       nd       nd          0.01          0.00        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          4B         nd        23.000000      174.920000     75       nd       nd          0.01          0.01        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          4B         nd        23.000000      174.920000     100      nd       nd          0.01          0.02        0.15        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          4B         nd        23.000000      174.920000     109      nd       nd          0.11          0.05        0.13        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          4B         nd        23.000000      174.920000     150      nd       nd          1.19          0.13        0.03        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          5          nd        23.000000      -180.000000    0        nd       nd          0.01          0.01        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          5          nd        23.000000      -180.000000    5        nd       nd          0.01          0.01        0.19        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          5          nd        23.000000      -180.000000    9        nd       nd          0.01          0.01        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          5          nd        23.000000      -180.000000    19       nd       nd          0.01          0.01        0.19        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          5          nd        23.000000      -180.000000    30       nd       nd          0.01          0.01        0.26        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          5          nd        23.000000      -180.000000    51       nd       nd          0.01          0.01        0.19        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          5          nd        23.000000      -180.000000    74       nd       nd          0.01          0.01        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          5          nd        23.000000      -180.000000    100      nd       nd          0.01          0.02        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          5          nd        23.000000      -180.000000    119      nd       nd          0.01          0.03        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          5          nd        23.000000      -180.000000    149      nd       nd          0.30          0.07        0.16        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          6          nd        23.000000      -170.000000    0        nd       nd          0.01          0.04        0.23        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          6          nd        23.000000      -170.000000    5        nd       nd          0.01          0.03        0.20        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          6          nd        23.000000      -170.000000    9        nd       nd          0.01          0.04        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          6          nd        23.000000      -170.000000    20       nd       nd          0.01          0.04        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          6          nd        23.000000      -170.000000    30       nd       nd          0.01          0.04        0.16        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          6          nd        23.000000      -170.000000    49       nd       nd          0.01          0.04        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          6          nd        23.000000      -170.000000    76       nd       nd          0.03          0.04        0.19        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          6          nd        23.000000      -170.000000    98       nd       nd          0.22          0.10        0.24        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          6          nd        23.000000      -170.000000    110      nd       nd          0.39          0.12        0.16        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          6          nd        23.000000      -170.000000    150      nd       nd          2.09          0.22        0.20        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          7          nd        23.000000      -165.000000    0        nd       nd          0.01          0.02        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          7          nd        23.000000      -165.000000    5        nd       nd          0.01          0.03        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          7          nd        23.000000      -165.000000    10       nd       nd          0.01          0.02        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          7          nd        23.000000      -165.000000    20       nd       nd          0.01          0.02        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          7          nd        23.000000      -165.000000    30       nd       nd          0.01          0.02        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          7          nd        23.000000      -165.000000    50       nd       nd          0.01          0.02        0.16        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          7          nd        23.000000      -165.000000    75       nd       nd          0.01          0.02        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          7          nd        23.000000      -165.000000    97       nd       nd          0.06          0.05        0.15        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          7          nd        23.000000      -165.000000    99       nd       nd          0.04          0.05        0.16        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          7          nd        23.000000      -165.000000    125      nd       nd          0.66          0.07        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          7          nd        23.000000      -165.000000    148      nd       nd          2.26          0.19        0.16        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          8          nd        22.770000      -158.090000    0        nd       nd          0.01          0.05        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          8          nd        22.770000      -158.090000    5        nd       nd          0.01          0.05        0.19        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          8          nd        22.770000      -158.090000    10       nd       nd          0.01          0.05        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          8          nd        22.770000      -158.090000    19       nd       nd          0.01          0.05        0.23        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          8          nd        22.770000      -158.090000    30       nd       nd          0.01          0.05        0.23        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          8          nd        22.770000      -158.090000    50       nd       nd          0.01          0.06        0.22        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          8          nd        22.770000      -158.090000    75       nd       nd          0.01          0.05        0.22        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          8          nd        22.770000      -158.090000    100      nd       nd          0.07          0.05        0.23        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          8          nd        22.770000      -158.090000    105      nd       nd          0.37          0.08        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          8          nd        22.770000      -158.090000    148      nd       nd          1.02          0.12        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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         nd          15         nd        -23.000000     -120.000000    0        nd       nd          0.01          0.22        0.12        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         nd          15         nd        -23.000000     -120.000000    5        nd       nd          0.01          0.24        0.14        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         nd          15         nd        -23.000000     -120.000000    11       nd       nd          0.01          0.23        0.10        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         nd          15         nd        -23.000000     -120.000000    20       nd       nd          0.01          0.22        0.08        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         nd          15         nd        -23.000000     -120.000000    30       nd       nd          0.01          0.20        0.09        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         nd          15         nd        -23.000000     -120.000000    50       nd       nd          0.01          0.19        0.15        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         nd          15         nd        -23.000000     -120.000000    75       nd       nd          0.01          0.19        0.03        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         nd          15         nd        -23.000000     -120.000000    99       nd       nd          0.01          0.19        0.07        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         nd          15         nd        -23.000000     -120.000000    123      nd       nd          0.01          0.17        0.09        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         nd          15         nd        -23.000000     -120.000000    149      nd       nd          0.01          0.16        0.10        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         nd          16         nd        -26.500000     -120.000000    0        nd       nd          0.01          0.11        0.21        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         nd          16         nd        -26.500000     -120.000000    6        nd       nd          0.01          0.12        0.20        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         nd          16         nd        -26.500000     -120.000000    10       nd       nd          0.01          0.12        0.23        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         nd          16         nd        -26.500000     -120.000000    20       nd       nd          0.01          0.12        0.20        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         nd          16         nd        -26.500000     -120.000000    30       nd       nd          0.01          0.13        0.16        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         nd          16         nd        -26.500000     -120.000000    50       nd       nd          0.01          0.12        0.19        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         nd          16         nd        -26.500000     -120.000000    75       nd       nd          0.01          0.12        0.18        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         nd          16         nd        -26.500000     -120.000000    99       nd       nd          0.01          0.11        0.16        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         nd          16         nd        -26.500000     -120.000000    124      nd       nd          0.01          0.11        0.16        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         nd          16         nd        -26.500000     -120.000000    148      nd       nd          0.01          0.12        0.20        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         nd          17         nd        -30.000000     -120.000000    0        nd       nd          0.01          0.08        0.17        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         nd          17         nd        -30.000000     -120.000000    5        nd       nd          0.01          0.09        0.17        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         nd          17         nd        -30.000000     -120.000000    10       nd       nd          0.01          0.09        0.16        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         nd          17         nd        -30.000000     -120.000000    20       nd       nd          0.01          0.09        0.16        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         nd          17         nd        -30.000000     -120.000000    30       nd       nd          0.01          0.09        0.17        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         nd          17         nd        -30.000000     -120.000000    49       nd       nd          0.01          0.09        0.16        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         nd          17         nd        -30.000000     -120.000000    75       nd       nd          0.01          0.10        0.16        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         nd          17         nd        -30.000000     -120.000000    100      nd       nd          0.01          0.12        0.16        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         nd          17         nd        -30.000000     -120.000000    125      nd       nd          0.01          0.13        0.17        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         nd          17         nd        -30.000000     -120.000000    150      nd       nd          0.10          0.16        0.17        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         nd          18         nd        -30.000000     -107.000000    0        nd       nd          0.01          0.12        0.18        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         nd          18         nd        -30.000000     -107.000000    5        nd       nd          0.01          0.13        0.19        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         nd          18         nd        -30.000000     -107.000000    10       nd       nd          0.01          0.13        0.16        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         nd          18         nd        -30.000000     -107.000000    20       nd       nd          0.01          0.13        0.17        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         nd          18         nd        -30.000000     -107.000000    31       nd       nd          0.01          0.13        0.18        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         nd          18         nd        -30.000000     -107.000000    50       nd       nd          0.01          0.12        0.18        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         nd          18         nd        -30.000000     -107.000000    75       nd       nd          0.01          0.12        0.18        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         nd          18         nd        -30.000000     -107.000000    100      nd       nd          0.01          0.13        0.16        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         nd          18         nd        -30.000000     -107.000000    124      nd       nd          0.01          0.14        0.14        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         nd          18         nd        -30.000000     -107.000000    149      nd       nd          0.05          0.17        0.12        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         nd          19         nd        -30.000000     -100.000000    0        nd       nd          0.01          0.16        0.15        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         nd          19         nd        -30.000000     -100.000000    5        nd       nd          0.01          0.15        0.17        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         nd          19         nd        -30.000000     -100.000000    10       nd       nd          0.01          0.16        0.18        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         nd          19         nd        -30.000000     -100.000000    19       nd       nd          0.01          0.15        0.19        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         nd          19         nd        -30.000000     -100.000000    30       nd       nd          0.01          0.16        0.15        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         nd          19         nd        -30.000000     -100.000000    50       nd       nd          0.01          0.14        0.19        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         nd          19         nd        -30.000000     -100.000000    75       nd       nd          0.01          0.14        0.16        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         nd          19         nd        -30.000000     -100.000000    99       nd       nd          0.01          0.14        0.13        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         nd          19         nd        -30.000000     -100.000000    125      nd       nd          0.03          0.17        0.12        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         nd          19         nd        -30.000000     -100.000000    126      nd       nd          0.05          0.18        0.12        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         nd          19         nd        -30.000000     -100.000000    150      nd       nd          0.89          0.21        0.12        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         nd          20         nd        -26.500000     -100.000000    0        nd       nd          0.01          0.18        0.16        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         nd          20         nd        -26.500000     -100.000000    5        nd       nd          0.01          0.19        0.16        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         nd          20         nd        -26.500000     -100.000000    10       nd       nd          0.01          0.19        0.16        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         nd          20         nd        -26.500000     -100.000000    20       nd       nd          0.01          0.19        0.18        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         nd          20         nd        -26.500000     -100.000000    29       nd       nd          0.01          0.19        0.17        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         nd          20         nd        -26.500000     -100.000000    49       nd       nd          0.01          0.19        0.15        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         nd          20         nd        -26.500000     -100.000000    75       nd       nd          0.01          0.18        0.15        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         nd          20         nd        -26.500000     -100.000000    99       nd       nd          0.01          0.18        0.17        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         nd          20         nd        -26.500000     -100.000000    124      nd       nd          0.01          0.19        0.16        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         nd          20         nd        -26.500000     -100.000000    149      nd       nd          0.02          0.19        0.14        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         nd          21         nd        -23.000000     -100.000000    0        nd       nd          0.01          0.26        0.20        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         nd          21         nd        -23.000000     -100.000000    5        nd       nd          0.01          0.26        0.04        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         nd          21         nd        -23.000000     -100.000000    10       nd       nd          0.01          0.30        0.21        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         nd          21         nd        -23.000000     -100.000000    20       nd       nd          0.01          0.30        0.20        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         nd          21         nd        -23.000000     -100.000000    29       nd       nd          0.01          0.29        0.20        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         nd          21         nd        -23.000000     -100.000000    49       nd       nd          0.01          0.25        0.17        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         nd          21         nd        -23.000000     -100.000000    75       nd       nd          0.01          0.23        0.17        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         nd          21         nd        -23.000000     -100.000000    99       nd       nd          0.01          0.21        0.10        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         nd          21         nd        -23.000000     -100.000000    124      nd       nd          0.01          0.23        0.08        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         nd          21         nd        -23.000000     -100.000000    149      nd       nd          0.03          0.24        0.15        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         nd          22         nd        -20.000000     -100.000000    0        nd       nd          0.02          0.34        0.28        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         nd          22         nd        -20.000000     -100.000000    5        nd       nd          0.02          0.34        0.27        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         nd          22         nd        -20.000000     -100.000000    10       nd       nd          0.02          0.36        0.31        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         nd          22         nd        -20.000000     -100.000000    21       nd       nd          0.02          0.36        0.29        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         nd          22         nd        -20.000000     -100.000000    30       nd       nd          0.01          0.30        0.17        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         nd          22         nd        -20.000000     -100.000000    49       nd       nd          0.01          0.30        0.22        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         nd          22         nd        -20.000000     -100.000000    74       nd       nd          0.01          0.30        0.21        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         nd          22         nd        -20.000000     -100.000000    99       nd       nd          0.01          0.27        0.15        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         nd          22         nd        -20.000000     -100.000000    125      nd       nd          0.01          0.27        0.12        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         nd          22         nd        -20.000000     -100.000000    148      nd       nd          0.13          0.28        0.14        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         nd          22         nd        -20.000000     -100.000000    151      nd       nd          0.27          0.28        0.18        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          nd          5          nd        35.000000      160.000000     0        nd       nd          0.01          0.01        0.09        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          5          nd        35.000000      160.000000     5        nd       nd          0.01          0.01        0.10        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          5          nd        35.000000      160.000000     10       nd       nd          0.01          0.01        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          5          nd        35.000000      160.000000     20       nd       nd          0.01          0.01        0.10        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          5          nd        35.000000      160.000000     30       nd       nd          0.01          0.02        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          5          nd        35.000000      160.000000     39       nd       nd          0.06          0.02        0.09        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          5          nd        35.000000      160.000000     50       nd       nd          0.00          0.04        0.09        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          5          nd        35.000000      160.000000     63       nd       nd          1.44          0.16        0.10        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          5          nd        35.000000      160.000000     75       nd       nd          2.18          0.14        0.09        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          5          nd        35.000000      160.000000     99       nd       nd          2.73          0.19        0.07        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          5          nd        35.000000      160.000000     149      nd       nd          3.73          0.25        0.06        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        30.000000      160.000000     0        nd       nd          0.01          0.00        0.07        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        30.000000      160.000000     5        nd       nd          0.01          0.00        0.08        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        30.000000      160.000000     10       nd       nd          0.01          0.00        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        30.000000      160.000000     20       nd       nd          0.01          0.00        0.08        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        30.000000      160.000000     30       nd       nd          0.01          0.00        0.08        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        30.000000      160.000000     40       nd       nd          0.01          0.01        0.08        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        30.000000      160.000000     50       nd       nd          0.01          0.01        0.08        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        30.000000      160.000000     75       nd       nd          1.22          0.13        0.08        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        30.000000      160.000000     86       nd       nd          1.95          0.17        0.10        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        30.000000      160.000000     99       nd       nd          2.82          0.22        0.03        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        30.000000      160.000000     150      nd       nd          4.02          0.26        0.08        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        25.000000      160.000000     0        nd       nd          0.01          0.00        0.10        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        25.000000      160.000000     5        nd       nd          0.01          0.00        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        25.000000      160.000000     10       nd       nd          0.01          0.00        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        25.000000      160.000000     20       nd       nd          0.01          0.00        0.11        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        25.000000      160.000000     30       nd       nd          0.01          0.01        0.11        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        25.000000      160.000000     40       nd       nd          0.01          0.00        0.07        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        25.000000      160.000000     50       nd       nd          0.01          0.00        0.10        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        25.000000      160.000000     75       nd       nd          0.01          0.00        0.08        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        25.000000      160.000000     100      nd       nd          0.01          0.01        0.07        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        25.000000      160.000000     137      nd       nd          0.44          0.07        0.11        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        25.000000      160.000000     149      nd       nd          2.24          0.18        0.04        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          9          nd        20.000000      160.000000     0        nd       nd          0.01          0.00        0.13        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          9          nd        20.000000      160.000000     5        nd       nd          0.01          0.00        0.13        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          9          nd        20.000000      160.000000     10       nd       nd          0.01          0.01        0.16        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          9          nd        20.000000      160.000000     20       nd       nd          0.01          0.00        0.13        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          9          nd        20.000000      160.000000     31       nd       nd          0.01          0.00        0.13        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          9          nd        20.000000      160.000000     40       nd       nd          0.01          0.00        0.11        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          9          nd        20.000000      160.000000     50       nd       nd          0.01          0.00        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          9          nd        20.000000      160.000000     76       nd       nd          0.01          0.00        0.10        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          9          nd        20.000000      160.000000     98       nd       nd          0.04          0.03        0.09        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          9          nd        20.000000      160.000000     126      nd       nd          0.00          0.02        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          9          nd        20.000000      160.000000     149      nd       nd          1.27          0.12        0.06        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          10         nd        15.000000      160.000000     0        nd       nd          0.01          0.07        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          10         nd        15.000000      160.000000     5        nd       nd          0.01          0.07        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          10         nd        15.000000      160.000000     10       nd       nd          0.01          0.08        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          10         nd        15.000000      160.000000     20       nd       nd          0.01          0.08        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          10         nd        15.000000      160.000000     30       nd       nd          0.01          0.08        0.15        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          10         nd        15.000000      160.000000     40       nd       nd          0.01          0.08        0.16        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          10         nd        15.000000      160.000000     50       nd       nd          0.01          0.07        0.16        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          10         nd        15.000000      160.000000     74       nd       nd          0.01          0.05        0.13        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          10         nd        15.000000      160.000000     99       nd       nd          0.01          0.03        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          10         nd        15.000000      160.000000     122      nd       nd          0.04          0.04        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          10         nd        15.000000      160.000000     149      nd       nd          0.59          0.14        0.07        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          12         nd        20.000000      148.000000     0        nd       nd          0.01          0.01        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          12         nd        20.000000      148.000000     5        nd       nd          0.01          0.01        0.13        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          12         nd        20.000000      148.000000     11       nd       nd          0.01          0.01        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          12         nd        20.000000      148.000000     20       nd       nd          0.01          0.01        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          12         nd        20.000000      148.000000     29       nd       nd          0.01          0.00        0.13        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          12         nd        20.000000      148.000000     40       nd       nd          0.01          0.00        0.13        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          12         nd        20.000000      148.000000     52       nd       nd          0.01          0.01        0.11        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          12         nd        20.000000      148.000000     75       nd       nd          0.01          0.01        0.10        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          12         nd        20.000000      148.000000     101      nd       nd          0.01          0.01        0.09        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          12         nd        20.000000      148.000000     129      nd       nd          0.46          0.06        0.10        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          12         nd        20.000000      148.000000     150      nd       nd          2.28          0.17        0.08        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          14         nd        24.000000      143.210000     0        nd       nd          0.01          0.00        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          14         nd        24.000000      143.210000     5        nd       nd          0.01          0.00        0.11        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          14         nd        24.000000      143.210000     9        nd       nd          0.01          0.00        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          14         nd        24.000000      143.210000     21       nd       nd          0.01          0.00        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          14         nd        24.000000      143.210000     30       nd       nd          0.01          0.00        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          14         nd        24.000000      143.210000     39       nd       nd          0.01          0.00        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          14         nd        24.000000      143.210000     49       nd       nd          0.01          0.00        0.11        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          14         nd        24.000000      143.210000     72       nd       nd          0.01          0.00        0.10        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          14         nd        24.000000      143.210000     88       nd       nd          0.01          0.01        0.09        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          14         nd        24.000000      143.210000     99       nd       nd          0.01          0.01        0.10        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          14         nd        24.000000      143.210000     149      nd       nd          1.28          0.10        0.08        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          15         nd        28.000000      138.000000     0        nd       nd          0.01          0.00        0.10        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          15         nd        28.000000      138.000000     5        nd       nd          0.01          0.00        0.10        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          15         nd        28.000000      138.000000     9        nd       nd          0.01          0.00        0.10        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          15         nd        28.000000      138.000000     20       nd       nd          0.01          0.00        0.10        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          15         nd        28.000000      138.000000     30       nd       nd          0.01          0.00        0.10        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          15         nd        28.000000      138.000000     39       nd       nd          0.01          0.00        0.10        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          15         nd        28.000000      138.000000     50       nd       nd          0.02          0.00        0.10        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          15         nd        28.000000      138.000000     75       nd       nd          0.27          0.04        0.09        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          15         nd        28.000000      138.000000     80       nd       nd          1.04          0.09        0.09        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          15         nd        28.000000      138.000000     99       nd       nd          1.85          0.13        0.10        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          15         nd        28.000000      138.000000     149      nd       nd          2.15          0.15        0.10        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          16         nd        31.000000      134.070000     0        nd       nd          0.01          0.01        0.10        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          16         nd        31.000000      134.070000     6        nd       nd          0.01          0.01        0.09        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          16         nd        31.000000      134.070000     10       nd       nd          0.01          0.01        0.09        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          16         nd        31.000000      134.070000     20       nd       nd          0.01          0.00        0.09        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          16         nd        31.000000      134.070000     30       nd       nd          0.01          0.01        0.09        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          16         nd        31.000000      134.070000     40       nd       nd          0.01          0.01        0.10        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          16         nd        31.000000      134.070000     50       nd       nd          0.01          0.01        0.09        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          16         nd        31.000000      134.070000     75       nd       nd          0.01          0.01        0.09        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          16         nd        31.000000      134.070000     100      nd       nd          0.00          0.07        0.05        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          16         nd        31.000000      134.070000     105      nd       nd          0.07          0.04        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          16         nd        31.000000      134.070000     150      nd       nd          2.34          0.16        0.06        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          0          nd        20.000000      160.010000     0        nd       nd          0.02          0.02        0.32        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          0          nd        20.000000      160.010000     5        nd       nd          0.01          0.01        0.30        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          0          nd        20.000000      160.010000     10       nd       nd          0.01          0.01        0.30        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          0          nd        20.000000      160.010000     20       nd       nd          0.01          0.01        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          0          nd        20.000000      160.010000     31       nd       nd          0.01          0.01        0.25        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          0          nd        20.000000      160.010000     50       nd       nd          0.01          0.01        0.19        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          0          nd        20.000000      160.010000     75       nd       nd          0.02          0.01        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          0          nd        20.000000      160.010000     100      nd       nd          0.01          0.01        0.15        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          0          nd        20.000000      160.010000     124      nd       nd          0.20          0.04        0.13        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          0          nd        20.000000      160.010000     126      nd       nd          0.26          0.05        0.24        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          0          nd        20.000000      160.010000     149      nd       nd          2.38          0.17        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          4          nd        -15.000000     -170.000000    0        nd       nd          0.02          0.21        0.23        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          nd          4          nd        -15.000000     -170.000000    10       nd       nd          0.02          0.22        0.21        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          nd          4          nd        -15.000000     -170.000000    21       nd       nd          0.01          0.22        0.21        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          nd          4          nd        -15.000000     -170.000000    30       nd       nd          0.01          0.22        0.19        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          nd          4          nd        -15.000000     -170.000000    50       nd       nd          0.01          0.23        0.21        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          nd          4          nd        -15.000000     -170.000000    76       nd       nd          0.01          0.21        0.20        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          nd          4          nd        -15.000000     -170.000000    98       nd       nd          0.01          0.23        0.17        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          nd          4          nd        -15.000000     -170.000000    126      nd       nd          0.59          0.31        0.11        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          nd          4          nd        -15.000000     -170.000000    139      nd       nd          2.09          0.41        0.06        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          nd          4          nd        -15.000000     -170.000000    149      nd       nd          3.02          0.47        0.03        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          nd          5          nd        -20.000000     -170.060000    0        nd       nd          0.02          0.13        0.20        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          nd          5          nd        -20.000000     -170.060000    4        nd       nd          0.01          0.13        0.18        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          nd          5          nd        -20.000000     -170.060000    9        nd       nd          0.01          0.13        0.18        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          nd          5          nd        -20.000000     -170.060000    20       nd       nd          0.01          0.13        0.17        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          nd          5          nd        -20.000000     -170.060000    30       nd       nd          0.01          0.13        0.17        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          nd          5          nd        -20.000000     -170.060000    49       nd       nd          0.01          0.10        0.17        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          nd          5          nd        -20.000000     -170.060000    75       nd       nd          0.01          0.07        0.14        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          nd          5          nd        -20.000000     -170.060000    99       nd       nd          0.01          0.07        0.14        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          nd          5          nd        -20.000000     -170.060000    124      nd       nd          0.01          0.09        0.12        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          nd          5          nd        -20.000000     -170.060000    150      nd       nd          0.11          0.13        0.10        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          nd          6          nd        -25.010000     -170.700000    0        nd       nd          0.01          0.03        0.18        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          nd          6          nd        -25.010000     -170.700000    5        nd       nd          0.01          0.03        0.17        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          nd          6          nd        -25.010000     -170.700000    10       nd       nd          0.01          0.03        0.14        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          nd          6          nd        -25.010000     -170.700000    21       nd       nd          0.01          0.03        0.17        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          nd          6          nd        -25.010000     -170.700000    30       nd       nd          0.01          0.03        0.16        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          nd          6          nd        -25.010000     -170.700000    50       nd       nd          0.01          0.03        0.12        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          nd          6          nd        -25.010000     -170.700000    75       nd       nd          0.01          0.07        0.13        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          nd          6          nd        -25.010000     -170.700000    100      nd       nd          0.40          0.15        0.07        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          nd          6          nd        -25.010000     -170.700000    109      nd       nd          0.93          0.20        0.10        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          nd          6          nd        -25.010000     -170.700000    124      nd       nd          2.26          0.27        0.05        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          nd          6          nd        -25.010000     -170.700000    148      nd       nd          3.22          0.33        0.03        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          nd          7          nd        -30.000000     -170.000000    0        nd       nd          0.01          0.03        0.14        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          nd          7          nd        -30.000000     -170.000000    10       nd       nd          0.01          0.03        0.14        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          nd          7          nd        -30.000000     -170.000000    21       nd       nd          0.01          0.03        0.12        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          nd          7          nd        -30.000000     -170.000000    31       nd       nd          0.01          0.03        0.11        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          nd          7          nd        -30.000000     -170.000000    49       nd       nd          0.01          0.06        0.12        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          nd          7          nd        -30.000000     -170.000000    75       nd       nd          0.01          0.10        0.12        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          nd          7          nd        -30.000000     -170.000000    99       nd       nd          0.03          0.14        0.11        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          nd          7          nd        -30.000000     -170.000000    107      nd       nd          0.84          0.22        0.06        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          nd          7          nd        -30.000000     -170.000000    124      nd       nd          3.23          0.35        0.02        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          nd          7          nd        -30.000000     -170.000000    149      nd       nd          4.87          0.45        0.04        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          nd          8          nd        -35.000000     -170.070000    0        nd       nd          0.01          0.08        0.12        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          nd          8          nd        -35.000000     -170.070000    6        nd       nd          0.01          0.08        0.12        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          nd          8          nd        -35.000000     -170.070000    10       nd       nd          0.01          0.08        0.12        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          nd          8          nd        -35.000000     -170.070000    21       nd       nd          0.01          0.08        0.11        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          nd          8          nd        -35.000000     -170.070000    30       nd       nd          0.01          0.08        0.11        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          nd          8          nd        -35.000000     -170.070000    49       nd       nd          0.01          0.08        0.12        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          nd          8          nd        -35.000000     -170.070000    75       nd       nd          0.01          0.08        0.12        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          nd          8          nd        -35.000000     -170.070000    99       nd       nd          0.01          0.10        0.10        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          nd          8          nd        -35.000000     -170.070000    123      nd       nd          0.15          0.18        0.09        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          nd          8          nd        -35.000000     -170.070000    126      nd       nd          0.68          0.28        0.02        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          nd          8          nd        -35.000000     -170.070000    148      nd       nd          4.39          0.44        0.02        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          nd          0          nd        19.990000      159.970000     0        nd       nd          0.01          0.00        0.36        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          0          nd        19.990000      159.970000     0        nd       nd          0.01          0.01        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          0          nd        19.990000      159.970000     5        nd       nd          0.01          0.00        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          0          nd        19.990000      159.970000     10       nd       nd          0.01          0.00        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          0          nd        19.990000      159.970000     20       nd       nd          0.01          0.00        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          0          nd        19.990000      159.970000     28       nd       nd          0.01          0.00        0.22        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          0          nd        19.990000      159.970000     30       nd       nd          0.01          0.00        0.23        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          0          nd        19.990000      159.970000     50       nd       nd          0.01          0.01        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          0          nd        19.990000      159.970000     55       nd       nd          0.01          0.00        0.24        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          0          nd        19.990000      159.970000     74       nd       nd          0.01          0.01        0.25        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          0          nd        19.990000      159.970000     100      nd       nd          0.01          0.01        0.22        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          0          nd        19.990000      159.970000     106      nd       nd          0.01          0.01        0.19        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          0          nd        19.990000      159.970000     119      nd       nd          0.08          0.03        0.24        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          0          nd        19.990000      159.970000     124      nd       nd          0.17          0.04        0.26        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          0          nd        19.990000      159.970000     148      nd       nd          1.38          0.13        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          4          nd        15.010000      -170.020000    0        nd       nd          0.01          0.14        0.30        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          4          nd        15.010000      -170.020000    0        nd       nd          0.01          0.14        0.20        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          4          nd        15.010000      -170.020000    5        nd       nd          0.01          0.14        0.29        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          4          nd        15.010000      -170.020000    10       nd       nd          0.01          0.14        0.36        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          4          nd        15.010000      -170.020000    19       nd       nd          0.01          0.14        0.27        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          4          nd        15.010000      -170.020000    20       nd       nd          0.01          0.14        0.19        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          4          nd        15.010000      -170.020000    30       nd       nd          0.01          0.14        0.34        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          4          nd        15.010000      -170.020000    48       nd       nd          0.01          0.14        0.26        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          4          nd        15.010000      -170.020000    50       nd       nd          0.01          0.14        0.36        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          4          nd        15.010000      -170.020000    75       nd       nd          0.01          0.14        0.39        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          4          nd        15.010000      -170.020000    100      nd       nd          0.01          0.13        0.37        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          4          nd        15.010000      -170.020000    116      nd       nd          0.03          0.13        0.26        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          4          nd        15.010000      -170.020000    125      nd       nd          0.06          0.15        0.27        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          4          nd        15.010000      -170.020000    134      nd       nd          0.36          0.19        0.25        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          4          nd        15.010000      -170.020000    149      nd       nd          0.59          0.21        0.31        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          5          nd        20.020000      -169.980000    0        nd       nd          0.01          0.12        0.25        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          5          nd        20.020000      -169.980000    0        nd       nd          0.01          0.12        0.19        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          5          nd        20.020000      -169.980000    5        nd       nd          0.01          0.12        0.26        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          5          nd        20.020000      -169.980000    10       nd       nd          0.01          0.12        0.27        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          5          nd        20.020000      -169.980000    20       nd       nd          0.01          0.12        0.26        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          5          nd        20.020000      -169.980000    20       nd       nd          0.01          0.11        0.29        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          5          nd        20.020000      -169.980000    30       nd       nd          0.01          0.10        0.24        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          5          nd        20.020000      -169.980000    47       nd       nd          0.01          0.06        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          5          nd        20.020000      -169.980000    51       nd       nd          0.01          0.05        0.20        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          5          nd        20.020000      -169.980000    74       nd       nd          0.01          0.05        0.22        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          5          nd        20.020000      -169.980000    100      nd       nd          0.01          0.07        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          5          nd        20.020000      -169.980000    100      nd       nd          0.01          0.05        0.19        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          5          nd        20.020000      -169.980000    124      nd       nd          0.06          0.09        0.20        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          5          nd        20.020000      -169.980000    138      nd       nd          0.72          0.15        0.23        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          5          nd        20.020000      -169.980000    144      nd       nd          1.59          0.19        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          5          nd        20.020000      -169.980000    151      nd       nd          1.95          0.24        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          6          nd        24.040000      -170.000000    0        nd       nd          0.01          0.04        0.20        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          6          nd        24.040000      -170.000000    0        nd       nd          0.01          0.04        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          6          nd        24.040000      -170.000000    5        nd       nd          0.01          0.03        0.22        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          6          nd        24.040000      -170.000000    10       nd       nd          0.01          0.04        0.23        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          6          nd        24.040000      -170.000000    20       nd       nd          0.01          0.03        0.24        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          6          nd        24.040000      -170.000000    25       nd       nd          0.01          0.03        0.19        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          6          nd        24.040000      -170.000000    30       nd       nd          0.01          0.02        0.19        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          6          nd        24.040000      -170.000000    50       nd       nd          0.01          0.02        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          6          nd        24.040000      -170.000000    54       nd       nd          0.01          0.03        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          6          nd        24.040000      -170.000000    75       nd       nd          0.01          0.04        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          6          nd        24.040000      -170.000000    100      nd       nd          0.01          0.05        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          6          nd        24.040000      -170.000000    108      nd       nd          0.94          0.12        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          6          nd        24.040000      -170.000000    113      nd       nd          0.42          0.09        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          6          nd        24.040000      -170.000000    124      nd       nd          2.20          0.21        0.15        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          6          nd        24.040000      -170.000000    149      nd       nd          2.55          0.23        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        30.040000      -170.000000    0        nd       nd          0.03          0.02        0.16        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        30.040000      -170.000000    0        nd       nd          0.01          0.02        0.16        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        30.040000      -170.000000    5        nd       nd          0.04          0.03        0.15        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        30.040000      -170.000000    10       nd       nd          0.06          0.02        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        30.040000      -170.000000    19       nd       nd          0.03          0.02        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        30.040000      -170.000000    27       nd       nd          0.01          0.02        0.08        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        30.040000      -170.000000    30       nd       nd          0.11          0.02        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        30.040000      -170.000000    50       nd       nd          0.07          0.04        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        30.040000      -170.000000    50       nd       nd          0.01          0.03        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        30.040000      -170.000000    73       nd       nd          0.05          0.07        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        30.040000      -170.000000    93       nd       nd          0.07          0.07        0.28        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        30.040000      -170.000000    99       nd       nd          0.78          0.19        0.09        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        30.040000      -170.000000    103      nd       nd          2.84          0.31        0.11        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        30.040000      -170.000000    124      nd       nd          4.09          0.42        0.04        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        30.040000      -170.000000    140      nd       nd          4.36          0.30        0.19        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        30.040000      -170.000000    148      nd       nd          4.60          0.36        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        35.010000      -170.000000    0        nd       nd          0.01          0.01        0.20        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        35.010000      -170.000000    0        nd       nd          0.01          0.02        0.19        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        35.010000      -170.000000    5        nd       nd          0.01          0.02        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        35.010000      -170.000000    10       nd       nd          0.01          0.02        0.19        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        35.010000      -170.000000    19       nd       nd          0.01          0.02        0.23        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        35.010000      -170.000000    22       nd       nd          0.01          0.03        0.15        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        35.010000      -170.000000    30       nd       nd          0.01          0.03        0.16        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        35.010000      -170.000000    40       nd       nd          0.01          0.04        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        35.010000      -170.000000    49       nd       nd          0.08          0.04        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        35.010000      -170.000000    66       nd       nd          2.01          0.14        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        35.010000      -170.000000    70       nd       nd          1.84          0.18        0.22        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        35.010000      -170.000000    74       nd       nd          3.09          0.28        0.15        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        35.010000      -170.000000    99       nd       nd          5.92          0.40        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        35.010000      -170.000000    99       nd       nd          5.61          0.38        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        35.010000      -170.000000    123      nd       nd          6.08          0.44        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        35.010000      -170.000000    151      nd       nd          6.75          0.41        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          6          nd        22.590000      -120.000000    0        nd       nd          0.01          0.18        0.23        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          6          nd        22.590000      -120.000000    0        nd       nd          0.01          0.19        0.20        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          6          nd        22.590000      -120.000000    6        nd       nd          0.01          0.18        0.22        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          6          nd        22.590000      -120.000000    11       nd       nd          0.01          0.19        0.22        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          6          nd        22.590000      -120.000000    20       nd       nd          0.01          0.19        0.22        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          6          nd        22.590000      -120.000000    28       nd       nd          0.01          0.21        0.19        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          6          nd        22.590000      -120.000000    31       nd       nd          0.01          0.19        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          6          nd        22.590000      -120.000000    51       nd       nd          0.01          0.21        0.20        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          6          nd        22.590000      -120.000000    51       nd       nd          0.01          0.22        0.19        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          6          nd        22.590000      -120.000000    76       nd       nd          0.01          0.23        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          6          nd        22.590000      -120.000000    99       nd       nd          0.06          0.24        0.16        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          6          nd        22.590000      -120.000000    104      nd       nd          0.06          0.24        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          6          nd        22.590000      -120.000000    119      nd       nd          2.38          0.68        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        23.000000      -130.000000    0        nd       nd          0.01          0.16        0.19        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        23.000000      -130.000000    0        nd       nd          0.01          0.17        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        23.000000      -130.000000    6        nd       nd          0.01          0.17        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        23.000000      -130.000000    10       nd       nd          0.01          0.17        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        23.000000      -130.000000    20       nd       nd          0.01          0.17        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        23.000000      -130.000000    26       nd       nd          0.01          0.18        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        23.000000      -130.000000    31       nd       nd          0.01          0.18        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        23.000000      -130.000000    50       nd       nd          0.01          0.16        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        23.000000      -130.000000    57       nd       nd          0.01          0.13        0.16        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        23.000000      -130.000000    74       nd       nd          0.01          0.15        0.15        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        23.000000      -130.000000    100      nd       nd          0.01          0.13        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        23.000000      -130.000000    116      nd       nd          0.03          0.12        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        23.000000      -130.000000    125      nd       nd          0.01          0.12        0.13        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        23.000000      -130.000000    140      nd       nd          0.57          0.17        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          7          nd        23.000000      -130.000000    150      nd       nd          1.70          0.29        0.08        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        22.590000      -140.000000    0        nd       nd          0.01          0.06        0.20        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        22.590000      -140.000000    0        nd       nd          0.01          0.06        0.20        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        22.590000      -140.000000    5        nd       nd          0.01          0.07        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        22.590000      -140.000000    10       nd       nd          0.01          0.07        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        22.590000      -140.000000    20       nd       nd          0.01          0.07        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        22.590000      -140.000000    24       nd       nd          0.01          0.07        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        22.590000      -140.000000    30       nd       nd          0.01          0.07        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        22.590000      -140.000000    51       nd       nd          0.01          0.06        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        22.590000      -140.000000    51       nd       nd          0.01          0.05        0.20        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        22.590000      -140.000000    75       nd       nd          0.01          0.09        0.19        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        22.590000      -140.000000    100      nd       nd          0.01          0.08        0.19        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        22.590000      -140.000000    110      nd       nd          0.01          0.11        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        22.590000      -140.000000    116      nd       nd          0.70          0.17        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        22.590000      -140.000000    125      nd       nd          1.03          0.18        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          8          nd        22.590000      -140.000000    150      nd       nd          1.16          0.18        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          9          nd        23.010000      -150.000000    0        nd       nd          0.01          0.10        0.23        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          9          nd        23.010000      -150.000000    0        nd       nd          0.01          0.10        0.24        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          9          nd        23.010000      -150.000000    5        nd       nd          0.01          0.10        0.22        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          9          nd        23.010000      -150.000000    10       nd       nd          0.01          0.10        0.23        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          9          nd        23.010000      -150.000000    20       nd       nd          0.01          0.08        0.23        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          9          nd        23.010000      -150.000000    25       nd       nd          0.01          0.10        0.24        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          9          nd        23.010000      -150.000000    31       nd       nd          0.01          0.05        0.22        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          9          nd        23.010000      -150.000000    50       nd       nd          0.01          0.02        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          9          nd        23.010000      -150.000000    51       nd       nd          0.01          0.04        0.22        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          9          nd        23.010000      -150.000000    75       nd       nd          0.01          0.03        0.22        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          9          nd        23.010000      -150.000000    100      nd       nd          0.01          0.04        0.19        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          9          nd        23.010000      -150.000000    106      nd       nd          0.01          0.07        0.19        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          9          nd        23.010000      -150.000000    118      nd       nd          0.63          0.21        0.09        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          9          nd        23.010000      -150.000000    124      nd       nd          0.96          0.18        0.15        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          9          nd        23.010000      -150.000000    149      nd       nd          2.87          0.38        0.03        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          10         nd        21.300000      -160.000000    0        nd       nd          0.01          0.07        0.20        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          10         nd        21.300000      -160.000000    0        nd       nd          0.01          0.06        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          10         nd        21.300000      -160.000000    6        nd       nd          0.01          0.06        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          10         nd        21.300000      -160.000000    11       nd       nd          0.01          0.07        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          10         nd        21.300000      -160.000000    20       nd       nd          0.01          0.07        0.20        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          10         nd        21.300000      -160.000000    25       nd       nd          0.01          0.06        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          10         nd        21.300000      -160.000000    31       nd       nd          0.01          0.07        0.22        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          10         nd        21.300000      -160.000000    48       nd       nd          0.01          0.07        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          10         nd        21.300000      -160.000000    49       nd       nd          0.01          0.09        0.21        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          10         nd        21.300000      -160.000000    75       nd       nd          0.01          0.07        0.20        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          10         nd        21.300000      -160.000000    101      nd       nd          0.09          0.14        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          10         nd        21.300000      -160.000000    104      nd       nd          0.04          0.15        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          10         nd        21.300000      -160.000000    111      nd       nd          0.18          0.15        0.16        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          10         nd        21.300000      -160.000000    125      nd       nd          0.25          0.14        0.16        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          10         nd        21.300000      -160.000000    148      nd       nd          0.92          0.19        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          10         nd        21.300000      -160.000000    149      nd       nd          0.80          0.17        0.13        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          11         nd        21.300000      -170.000000    0        nd       nd          0.01          0.04        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          11         nd        21.300000      -170.000000    0        nd       nd          0.01          0.04        0.16        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          11         nd        21.300000      -170.000000    5        nd       nd          0.01          0.05        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          11         nd        21.300000      -170.000000    10       nd       nd          0.01          0.04        0.19        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          11         nd        21.300000      -170.000000    20       nd       nd          0.01          0.02        0.19        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          11         nd        21.300000      -170.000000    29       nd       nd          0.01          0.01        0.19        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          11         nd        21.300000      -170.000000    29       nd       nd          0.01          0.03        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          11         nd        21.300000      -170.000000    51       nd       nd          0.01          0.01        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          11         nd        21.300000      -170.000000    57       nd       nd          0.01          0.03        0.15        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          11         nd        21.300000      -170.000000    74       nd       nd          0.01          0.01        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          11         nd        21.300000      -170.000000    100      nd       nd          0.01          0.03        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          11         nd        21.300000      -170.000000    108      nd       nd          0.01          0.08        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          11         nd        21.300000      -170.000000    121      nd       nd          0.66          0.15        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          11         nd        21.300000      -170.000000    124      nd       nd          0.97          0.17        0.11        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          11         nd        21.300000      -170.000000    144      nd       nd          1.96          0.28        0.09        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          11         nd        21.300000      -170.000000    148      nd       nd          1.87          0.27        0.06        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          12         nd        22.590000      179.590000     0        nd       nd          0.01          0.03        0.16        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          12         nd        22.590000      179.590000     0        nd       nd          0.01          0.02        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          12         nd        22.590000      179.590000     5        nd       nd          0.01          0.02        0.16        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          12         nd        22.590000      179.590000     11       nd       nd          0.01          0.03        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          12         nd        22.590000      179.590000     20       nd       nd          0.01          0.02        0.17        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          12         nd        22.590000      179.590000     25       nd       nd          0.01          0.01        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          12         nd        22.590000      179.590000     29       nd       nd          0.01          0.03        0.16        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          12         nd        22.590000      179.590000     50       nd       nd          0.01          0.03        0.16        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          12         nd        22.590000      179.590000     52       nd       nd          0.01          0.01        0.18        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          12         nd        22.590000      179.590000     74       nd       nd          0.01          0.03        0.15        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          12         nd        22.590000      179.590000     100      nd       nd          0.01          0.04        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          12         nd        22.590000      179.590000     111      nd       nd          0.01          0.05        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          12         nd        22.590000      179.590000     125      nd       nd          0.09          0.11        0.10        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          12         nd        22.590000      179.590000     131      nd       nd          0.41          0.11        0.11        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          12         nd        22.590000      179.590000     151      nd       nd          0.82          0.18        0.06        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          13         nd        23.000000      169.590000     0        nd       nd          0.01          0.00        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          13         nd        23.000000      169.590000     0        nd       nd          0.01          0.00        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          13         nd        23.000000      169.590000     5        nd       nd          0.01          0.00        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          13         nd        23.000000      169.590000     10       nd       nd          0.01          0.01        0.15        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          13         nd        23.000000      169.590000     21       nd       nd          0.01          0.01        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          13         nd        23.000000      169.590000     27       nd       nd          0.01          0.00        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          13         nd        23.000000      169.590000     31       nd       nd          0.01          0.01        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          13         nd        23.000000      169.590000     49       nd       nd          0.01          0.00        0.13        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          13         nd        23.000000      169.590000     56       nd       nd          0.01          0.00        0.13        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          13         nd        23.000000      169.590000     76       nd       nd          0.01          0.03        0.16        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          13         nd        23.000000      169.590000     99       nd       nd          0.01          0.04        0.11        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          13         nd        23.000000      169.590000     113      nd       nd          0.01          0.04        0.13        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          13         nd        23.000000      169.590000     125      nd       nd          0.17          0.10        0.10        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          13         nd        23.000000      169.590000     126      nd       nd          0.13          0.09        0.13        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          13         nd        23.000000      169.590000     149      nd       nd          1.00          0.21        0.04        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          14         nd        22.590000      159.580000     0        nd       nd          0.01          0.00        0.15        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          14         nd        22.590000      159.580000     0        nd       nd          0.01          0.00        0.19        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          14         nd        22.590000      159.580000     6        nd       nd          0.01          0.00        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          14         nd        22.590000      159.580000     11       nd       nd          0.01          0.00        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          14         nd        22.590000      159.580000     20       nd       nd          0.01          0.00        0.15        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          14         nd        22.590000      159.580000     28       nd       nd          0.01          0.00        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          14         nd        22.590000      159.580000     30       nd       nd          0.01          0.00        0.13        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          14         nd        22.590000      159.580000     50       nd       nd          0.01          0.00        0.13        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          14         nd        22.590000      159.580000     56       nd       nd          0.01          0.00        0.15        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          14         nd        22.590000      159.580000     74       nd       nd          0.01          0.00        0.13        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          14         nd        22.590000      159.580000     99       nd       nd          0.01          0.02        0.13        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          14         nd        22.590000      159.580000     114      nd       nd          0.01          0.03        0.13        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          14         nd        22.590000      159.580000     125      nd       nd          0.01          0.03        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          14         nd        22.590000      159.580000     145      nd       nd          0.03          0.04        0.11        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          14         nd        22.590000      159.580000     150      nd       nd          0.05          0.04        0.11        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          15         nd        23.000000      150.010000     0        nd       nd          0.01          0.00        0.11        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          15         nd        23.000000      150.010000     0        nd       nd          0.01          0.00        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          15         nd        23.000000      150.010000     5        nd       nd          0.01          0.00        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          15         nd        23.000000      150.010000     20       nd       nd          0.01          0.00        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          15         nd        23.000000      150.010000     31       nd       nd          0.01          0.00        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          15         nd        23.000000      150.010000     33       nd       nd          0.01          0.00        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          15         nd        23.000000      150.010000     50       nd       nd          0.01          0.00        0.11        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          15         nd        23.000000      150.010000     57       nd       nd          0.01          0.00        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          15         nd        23.000000      150.010000     75       nd       nd          0.01          0.01        0.11        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          15         nd        23.000000      150.010000     100      nd       nd          0.01          0.04        0.11        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          15         nd        23.000000      150.010000     103      nd       nd          0.01          0.03        0.11        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          15         nd        23.000000      150.010000     115      nd       nd          0.38          0.10        0.09        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          15         nd        23.000000      150.010000     125      nd       nd          0.00          0.17        0.06        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          15         nd        23.000000      150.010000     137      nd       nd          1.00          0.13        0.08        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          15         nd        23.000000      150.010000     149      nd       nd          2.43          0.24        0.04        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          16         nd        23.000000      139.590000     0        nd       nd          0.01          0.00        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          16         nd        23.000000      139.590000     0        nd       nd          0.01          0.00        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          16         nd        23.000000      139.590000     5        nd       nd          0.01          0.00        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          16         nd        23.000000      139.590000     10       nd       nd          0.01          0.00        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          16         nd        23.000000      139.590000     20       nd       nd          0.01          0.00        0.13        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          16         nd        23.000000      139.590000     25       nd       nd          0.01          0.00        0.11        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          16         nd        23.000000      139.590000     30       nd       nd          0.01          0.00        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          16         nd        23.000000      139.590000     50       nd       nd          0.01          0.00        0.11        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          16         nd        23.000000      139.590000     53       nd       nd          0.01          0.01        0.11        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          16         nd        23.000000      139.590000     75       nd       nd          0.01          0.02        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          16         nd        23.000000      139.590000     99       nd       nd          0.25          0.08        0.10        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          16         nd        23.000000      139.590000     103      nd       nd          0.49          0.10        0.08        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          16         nd        23.000000      139.590000     106      nd       nd          0.94          0.13        0.08        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          16         nd        23.000000      139.590000     124      nd       nd          0.00          0.15        0.06        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          16         nd        23.000000      139.590000     149      nd       nd          1.46          0.16        0.07        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          16         nd        23.000000      139.590000     149      nd       nd          1.84          0.20        0.06        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          17         nd        23.000000      136.590000     0        nd       nd          0.01          0.00        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          17         nd        23.000000      136.590000     0        nd       nd          0.01          0.00        0.15        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          17         nd        23.000000      136.590000     5        nd       nd          0.01          0.00        0.15        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          17         nd        23.000000      136.590000     11       nd       nd          0.01          0.00        0.15        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          17         nd        23.000000      136.590000     20       nd       nd          0.01          0.00        0.15        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          17         nd        23.000000      136.590000     28       nd       nd          0.01          0.00        0.15        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          17         nd        23.000000      136.590000     30       nd       nd          0.01          0.00        0.16        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          17         nd        23.000000      136.590000     49       nd       nd          0.01          0.00        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          17         nd        23.000000      136.590000     60       nd       nd          0.01          0.00        0.15        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          17         nd        23.000000      136.590000     75       nd       nd          0.01          0.00        0.16        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          17         nd        23.000000      136.590000     99       nd       nd          0.01          0.01        0.14        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          17         nd        23.000000      136.590000     117      nd       nd          0.04          0.03        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          17         nd        23.000000      136.590000     123      nd       nd          0.05          0.04        0.12        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          17         nd        23.000000      136.590000     131      nd       nd          0.26          0.06        0.11        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical 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          nd          17         nd        23.000000      136.590000     149      nd       nd          0.61          0.08        0.10        North Pacific    Wet oxidation    Hashihama; F.; Saito; H.; Shiozaki; T.; Ehama; M.; Suwa; S.; Sugiyama; T.; et al. (2020). Biogeochemical controls of particulate phosphorus distribution across the oligotrophic subtropical Pacific Ocean. Global Biogeochemical Cycles; 34; e2020GB006669. https://doi.org/10.1029/2020GB006669  
nd                              AMT10            2000-04-13  A10-01     nd        -35.088020     -49.302280     11.9     nd       nd          nd            nd          0.01        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -35.088020     -49.302280     28.3     nd       nd          nd            nd          0.13        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -35.088020     -49.302280     41.7     nd       nd          nd            nd          0.12        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -35.088020     -49.302280     45.1     nd       nd          nd            nd          0.12        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -35.088020     -49.302280     71.6     nd       nd          nd            nd          0.19        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -35.088020     -49.302280     140      nd       nd          nd            nd          0.07        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -35.088020     -49.302280     189.8    nd       nd          nd            nd          0.14        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -29.047400     -43.023330     11.1     nd       nd          nd            nd          0.39        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -29.047400     -43.023330     46.6     nd       nd          nd            nd          0.39        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -22.248100     -36.839750     9.2      nd       nd          nd            nd          0.09        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -22.248100     -36.839750     32.5     nd       nd          nd            nd          0.16        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -22.248100     -36.839750     37.8     nd       nd          nd            nd          0.03        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -22.248100     -36.839750     47.3     nd       nd          nd            nd          0.01        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -22.248100     -36.839750     82.4     nd       nd          nd            nd          0.03        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -22.248100     -36.839750     92.3     nd       nd          nd            nd          0.02        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -22.248100     -36.839750     107.2    nd       nd          nd            nd          0.03        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -22.248100     -36.839750     136.6    nd       nd          nd            nd          0.02        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -22.248100     -36.839750     175.9    nd       nd          nd            nd          0.02        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -22.248100     -36.839750     251.3    nd       nd          nd            nd          0.10        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -14.183880     -32.652230     22.2     nd       nd          nd            nd          0.13        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -14.183880     -32.652230     66.5     nd       nd          nd            nd          0.06        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -14.183880     -32.652230     101.9    nd       nd          nd            nd          0.04        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -14.183880     -32.652230     136.4    nd       nd          nd            nd          0.06        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -14.183880     -32.652230     151.6    nd       nd          nd            nd          0.14        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -14.183880     -32.652230     250      nd       nd          nd            nd          0.02        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -13.513120     -32.327620     181.6    nd       nd          nd            nd          0.14        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -13.513120     -32.327620     230.4    nd       nd          nd            nd          0.05        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -13.513120     -32.327620     296.3    nd       nd          nd            nd          0.01        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -13.513120     -32.327620     489.4    nd       nd          nd            nd          0.01        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -10.286050     -30.831390     9.6      nd       nd          nd            nd          0.19        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -10.286050     -30.831390     31.8     nd       nd          nd            nd          0.35        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -10.286050     -30.831390     55.9     nd       nd          nd            nd          0.19        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -10.286050     -30.831390     101      nd       nd          nd            nd          0.14        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -10.286050     -30.831390     119.3    nd       nd          nd            nd          0.14        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -10.286050     -30.831390     126.3    nd       nd          nd            nd          0.08        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -10.286050     -30.831390     168      nd       nd          nd            nd          0.06        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -6.340290      -28.994400     10.3     nd       nd          nd            nd          0.09        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -6.340290      -28.994400     18.4     nd       nd          nd            nd          0.13        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -6.340290      -28.994400     23.6     nd       nd          nd            nd          0.12        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -6.340290      -28.994400     33.3     nd       nd          nd            nd          0.13        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -6.340290      -28.994400     58.2     nd       nd          nd            nd          0.13        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -6.340290      -28.994400     73.5     nd       nd          nd            nd          0.09        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -6.340290      -28.994400     83.2     nd       nd          nd            nd          0.12        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -6.340290      -28.994400     107.6    nd       nd          nd            nd          0.04        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -6.340290      -28.994400     249.7    nd       nd          nd            nd          0.13        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -2.225070      -27.100710     53       nd       nd          nd            nd          0.28        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -2.225070      -27.100710     102.5    nd       nd          nd            nd          0.25        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -2.225070      -27.100710     179.2    nd       nd          nd            nd          0.40        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -2.225070      -27.100710     252.9    nd       nd          nd            nd          0.38        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        1.942330       -25.260490     10.2     nd       nd          nd            nd          0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        1.942330       -25.260490     18.3     nd       nd          nd            nd          0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        1.942330       -25.260490     27.1     nd       nd          nd            nd          0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        1.942330       -25.260490     62.8     nd       nd          nd            nd          0.17        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        1.942330       -25.260490     73       nd       nd          nd            nd          0.54        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        1.942330       -25.260490     200.5    nd       nd          nd            nd          0.13        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        6.098090       -23.450300     9.3      nd       nd          nd            nd          0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        6.098090       -23.450300     17.6     nd       nd          nd            nd          0.14        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        6.098090       -23.450300     23       nd       nd          nd            nd          0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        6.098090       -23.450300     26.9     nd       nd          nd            nd          0.14        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        6.098090       -23.450300     37.2     nd       nd          nd            nd          0.16        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        6.098090       -23.450300     46.9     nd       nd          nd            nd          0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        6.098090       -23.450300     56.3     nd       nd          nd            nd          0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        6.098090       -23.450300     77.3     nd       nd          nd            nd          0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        6.098090       -23.450300     102.1    nd       nd          nd            nd          0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        10.204150      -21.655010     2.8      nd       nd          nd            nd          0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        10.204150      -21.655010     9.8      nd       nd          nd            nd          0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        10.204150      -21.655010     16.9     nd       nd          nd            nd          0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        10.204150      -21.655010     21.5     nd       nd          nd            nd          0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        10.204150      -21.655010     33.5     nd       nd          nd            nd          0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        10.204150      -21.655010     46.1     nd       nd          nd            nd          0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        10.204150      -21.655010     103.7    nd       nd          nd            nd          0.11        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        12.468720      -20.655770     10.3     nd       nd          nd            nd          0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        12.468720      -20.655770     50       nd       nd          nd            nd          0.16        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        12.468720      -20.655770     150.6    nd       nd          nd            nd          0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        23.682360      -21.562640     10.6     nd       nd          nd            nd          0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        23.682360      -21.562640     23.6     nd       nd          nd            nd          0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        23.682360      -21.562640     42.4     nd       nd          nd            nd          0.11        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        23.682360      -21.562640     71.4     nd       nd          nd            nd          0.11        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        23.682360      -21.562640     77       nd       nd          nd            nd          0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        23.682360      -21.562640     81.4     nd       nd          nd            nd          0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        23.682360      -21.562640     114.6    nd       nd          nd            nd          0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        23.682360      -21.562640     161.4    nd       nd          nd            nd          0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        27.533590      -21.962330     10.2     nd       nd          nd            nd          0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        27.533590      -21.962330     17.9     nd       nd          nd            nd          0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        27.533590      -21.962330     22.6     nd       nd          nd            nd          0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        27.533590      -21.962330     32.8     nd       nd          nd            nd          0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        27.533590      -21.962330     55.9     nd       nd          nd            nd          0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        27.533590      -21.962330     82.1     nd       nd          nd            nd          0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        27.533590      -21.962330     107.7    nd       nd          nd            nd          0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        27.533590      -21.962330     172      nd       nd          nd            nd          0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.999400      -19.994710     10.2     nd       nd          nd            nd          0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.999400      -19.994710     18.1     nd       nd          nd            nd          0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.999400      -19.994710     23.1     nd       nd          nd            nd          0.24        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.999400      -19.994710     32.9     nd       nd          nd            nd          0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.999400      -19.994710     42.7     nd       nd          nd            nd          0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.999400      -19.994710     53       nd       nd          nd            nd          0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.999400      -19.994710     62.7     nd       nd          nd            nd          0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.999400      -19.994710     76.8     nd       nd          nd            nd          0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.999400      -19.994710     102.3    nd       nd          nd            nd          0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.999400      -19.994710     152.1    nd       nd          nd            nd          0.11        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.999400      -19.994710     202      nd       nd          nd            nd          0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        38.866880      -20.003550     8.9      nd       nd          nd            nd          0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        38.866880      -20.003550     17       nd       nd          nd            nd          0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        38.866880      -20.003550     22.5     nd       nd          nd            nd          0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        38.866880      -20.003550     42.5     nd       nd          nd            nd          0.11        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        38.866880      -20.003550     61.1     nd       nd          nd            nd          0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        38.866880      -20.003550     110.2    nd       nd          nd            nd          0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        38.866880      -20.003550     125.3    nd       nd          nd            nd          0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        38.866880      -20.003550     138.9    nd       nd          nd            nd          0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        38.866880      -20.003550     198.4    nd       nd          nd            nd          0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        48.204720      -12.833780     9.7      nd       nd          nd            nd          0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        48.204720      -12.833780     22.4     nd       nd          nd            nd          0.20        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        48.204720      -12.833780     32.1     nd       nd          nd            nd          0.13        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        48.204720      -12.833780     51.3     nd       nd          nd            nd          0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        48.204720      -12.833780     76       nd       nd          nd            nd          0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        48.204720      -12.833780     98.7     nd       nd          nd            nd          0.16        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        48.204720      -12.833780     122.7    nd       nd          nd            nd          0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        48.204720      -12.833780     147.9    nd       nd          nd            nd          0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        49.319690      -6.004580      9.8      nd       nd          nd            nd          0.19        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        49.319690      -6.004580      17.8     nd       nd          nd            nd          0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        49.319690      -6.004580      22.4     nd       nd          nd            nd          0.11        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        49.319690      -6.004580      32.1     nd       nd          nd            nd          0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        49.319690      -6.004580      42.7     nd       nd          nd            nd          0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        49.319690      -6.004580      52.5     nd       nd          nd            nd          0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        49.319690      -6.004580      61.9     nd       nd          nd            nd          0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        49.319690      -6.004580      71.8     nd       nd          nd            nd          0.33        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -5.320860      -24.995980     0.7      nd       nd          nd            nd          0.02        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -5.320860      -24.995980     9.9      nd       nd          nd            nd          0.02        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -5.320860      -24.995980     24.5     nd       nd          nd            nd          0.04        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -5.320860      -24.995980     50.2     nd       nd          nd            nd          0.08        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -5.320860      -24.995980     74.6     nd       nd          nd            nd          0.02        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -5.320860      -24.995980     83.8     nd       nd          nd            nd          0.08        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -5.320860      -24.995980     124.5    nd       nd          nd            nd          0.02        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        2.211340       -26.306560     23.5     nd       nd          nd            nd          0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        2.211340       -26.306560     48.6     nd       nd          nd            nd          0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        2.211340       -26.306560     62.7     nd       nd          nd            nd          0.14        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        2.211340       -26.306560     99.2     nd       nd          nd            nd          0.11        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        5.916070       -28.483760     1.5      nd       nd          nd            nd          0.11        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        5.916070       -28.483760     9.9      nd       nd          nd            nd          0.14        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        5.916070       -28.483760     24.7     nd       nd          nd            nd          0.13        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        5.916070       -28.483760     49.2     nd       nd          nd            nd          0.14        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        5.916070       -28.483760     65.5     nd       nd          nd            nd          0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        5.916070       -28.483760     99.5     nd       nd          nd            nd          0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        5.916070       -28.483760     124.9    nd       nd          nd            nd          0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        5.916070       -28.483760     174.5    nd       nd          nd            nd          0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        9.563240       -30.677170     10.1     nd       nd          nd            nd          0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        9.563240       -30.677170     59.1     nd       nd          nd            nd          0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        12.235370      -32.286190     1.7      nd       nd          nd            nd          0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        12.235370      -32.286190     9.1      nd       nd          nd            nd          0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        12.235370      -32.286190     23.9     nd       nd          nd            nd          0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        15.448400      -34.230540     1.7      nd       nd          nd            nd          0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        15.448400      -34.230540     10.5     nd       nd          nd            nd          0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        15.448400      -34.230540     25.7     nd       nd          nd            nd          0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        15.448400      -34.230540     50.3     nd       nd          nd            nd          0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        15.448400      -34.230540     75.6     nd       nd          nd            nd          0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        15.448400      -34.230540     100.7    nd       nd          nd            nd          0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        15.448400      -34.230540     113.9    nd       nd          nd            nd          0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        15.448400      -34.230540     250.5    nd       nd          nd            nd          0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        19.050750      -36.455470     2.5      nd       nd          nd            nd          0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        19.050750      -36.455470     99.8     nd       nd          nd            nd          0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        19.050750      -36.455470     122.7    nd       nd          nd            nd          0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        19.050750      -36.455470     174.4    nd       nd          nd            nd          0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        22.231740      -34.900550     2.1      nd       nd          nd            nd          0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        22.231740      -34.900550     10.1     nd       nd          nd            nd          0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        22.231740      -34.900550     49.8     nd       nd          nd            nd          0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        22.231740      -34.900550     74.4     nd       nd          nd            nd          0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        22.231740      -34.900550     124.5    nd       nd          nd            nd          0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        22.231740      -34.900550     149.4    nd       nd          nd            nd          0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.329050      -32.573260     2.2      nd       nd          nd            nd          0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.329050      -32.573260     10.2     nd       nd          nd            nd          0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.329050      -32.573260     25.5     nd       nd          nd            nd          0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.329050      -32.573260     49.7     nd       nd          nd            nd          0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.329050      -32.573260     100.1    nd       nd          nd            nd          0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.329050      -32.573260     125.4    nd       nd          nd            nd          0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.329050      -32.573260     150.2    nd       nd          nd            nd          0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.329050      -32.573260     175.8    nd       nd          nd            nd          0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.329050      -32.573260     250.4    nd       nd          nd            nd          0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        27.212440      -29.299550     2        nd       nd          nd            nd          0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        27.212440      -29.299550     11.9     nd       nd          nd            nd          0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        27.212440      -29.299550     27.1     nd       nd          nd            nd          0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        27.212440      -29.299550     51.4     nd       nd          nd            nd          0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        27.212440      -29.299550     101.5    nd       nd          nd            nd          0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        27.212440      -29.299550     119.8    nd       nd          nd            nd          0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        27.212440      -29.299550     176.9    nd       nd          nd            nd          0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        27.212440      -29.299550     251.7    nd       nd          nd            nd          0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        27.212440      -29.299550     302      nd       nd          nd            nd          0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        30.290990      -25.721220     10.5     nd       nd          nd            nd          0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        30.290990      -25.721220     150.4    nd       nd          nd            nd          0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        30.290990      -25.721220     250.2    nd       nd          nd            nd          0.14        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        33.624210      -21.714810     2        nd       nd          nd            nd          0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        33.624210      -21.714810     10.5     nd       nd          nd            nd          0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        33.624210      -21.714810     75.2     nd       nd          nd            nd          0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        33.624210      -21.714810     94.9     nd       nd          nd            nd          0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        33.624210      -21.714810     125.1    nd       nd          nd            nd          0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        33.624210      -21.714810     250.3    nd       nd          nd            nd          0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        41.492470      -20.020170     1.9      nd       nd          nd            nd          0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        41.492470      -20.020170     17.2     nd       nd          nd            nd          0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        41.492470      -20.020170     23       nd       nd          nd            nd          0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        41.492470      -20.020170     48.7     nd       nd          nd            nd          0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        41.492470      -20.020170     75.7     nd       nd          nd            nd          0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        47.687970      -12.681950     1.4      nd       nd          nd            nd          0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        47.687970      -12.681950     3.1      nd       nd          nd            nd          0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        47.687970      -12.681950     22       nd       nd          nd            nd          0.51        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        47.687970      -12.681950     34.7     nd       nd          nd            nd          0.39        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -47.039320     -50.254970     15       nd       nd          nd            nd          0.09        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        -47.039320     -50.254970     20.2     nd       nd          nd            nd          0.08        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        -47.039320     -50.254970     25.1     nd       nd          nd            nd          0.07        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        -47.039320     -50.254970     30       nd       nd          nd            nd          0.07        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        -41.034890     -41.558720     8.6      nd       nd          nd            nd          0.18        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        -41.034890     -41.558720     18.6     nd       nd          nd            nd          0.02        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        -41.034890     -41.558720     33.1     nd       nd          nd            nd          0.14        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        -41.034890     -41.558720     65       nd       nd          nd            nd          0.13        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        -38.881490     -38.585390     17       nd       nd          nd            nd          0.11        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -38.881490     -38.585390     27.1     nd       nd          nd            nd          0.12        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -38.881490     -38.585390     36.7     nd       nd          nd            nd          0.09        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -38.881490     -38.585390     67.2     nd       nd          nd            nd          0.03        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -35.966670     -34.789970     9.2      nd       nd          nd            nd          0.16        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -35.966670     -34.789970     22.6     nd       nd          nd            nd          0.17        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -35.966670     -34.789970     40.7     nd       nd          nd            nd          0.07        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -35.966670     -34.789970     87.1     nd       nd          nd            nd          0.15        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -35.966670     -34.789970     120.5    nd       nd          nd            nd          0.10        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -32.973750     -31.007960     14.7     nd       nd          nd            nd          0.11        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -32.973750     -31.007960     25.2     nd       nd          nd            nd          0.22        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -32.973750     -31.007960     44.9     nd       nd          nd            nd          0.35        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -32.973750     -31.007960     101.2    nd       nd          nd            nd          0.06        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -29.768850     -27.094170     6.5      nd       nd          nd            nd          0.08        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -29.768850     -27.094170     24.7     nd       nd          nd            nd          0.08        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -29.768850     -27.094170     44       nd       nd          nd            nd          0.15        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -29.768850     -27.094170     104.1    nd       nd          nd            nd          0.18        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -29.768850     -27.094170     153.8    nd       nd          nd            nd          0.22        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -28.088230     -25.101990     24.3     nd       nd          nd            nd          0.09        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -28.088230     -25.101990     123.7    nd       nd          nd            nd          0.08        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -28.088230     -25.101990     157.7    nd       nd          nd            nd          0.08        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -24.231240     -24.995120     15       nd       nd          nd            nd          0.09        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -24.231240     -24.995120     26       nd       nd          nd            nd          0.15        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -24.231240     -24.995120     47.6     nd       nd          nd            nd          0.16        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -24.231240     -24.995120     120.3    nd       nd          nd            nd          0.14        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -24.231240     -24.995120     164.7    nd       nd          nd            nd          0.20        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -20.929630     -25.003790     20.2     nd       nd          nd            nd          0.19        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -20.929630     -25.003790     35.8     nd       nd          nd            nd          0.23        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -20.929630     -25.003790     64.2     nd       nd          nd            nd          0.25        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -16.644520     -24.996190     19.4     nd       nd          nd            nd          0.26        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -16.644520     -24.996190     35.4     nd       nd          nd            nd          0.26        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -16.644520     -24.996190     64.2     nd       nd          nd            nd          0.27        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -16.644520     -24.996190     149.4    nd       nd          nd            nd          0.24        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -16.644520     -24.996190     224.3    nd       nd          nd            nd          0.19        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -12.275930     -24.994430     129.7    nd       nd          nd            nd          0.14        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -8.817560      -25.002060     13.7     nd       nd          nd            nd          0.22        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -8.817560      -25.002060     24.9     nd       nd          nd            nd          0.22        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -8.817560      -25.002060     45.7     nd       nd          nd            nd          0.21        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -8.817560      -25.002060     102      nd       nd          nd            nd          0.37        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -8.817560      -25.002060     153.1    nd       nd          nd            nd          0.33        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -4.461850      -25.012490     11.8     nd       nd          nd            nd          0.25        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -4.461850      -25.012490     21.5     nd       nd          nd            nd          0.24        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -4.461850      -25.012490     39.2     nd       nd          nd            nd          0.24        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -4.461850      -25.012490     89.8     nd       nd          nd            nd          0.37        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -4.461850      -25.012490     137      nd       nd          nd            nd          0.26        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -0.101350      -24.996620     8        nd       nd          nd            nd          0.48        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -0.101350      -24.996620     15       nd       nd          nd            nd          0.49        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -0.101350      -24.996620     26.8     nd       nd          nd            nd          0.18        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -0.101350      -24.996620     59.1     nd       nd          nd            nd          0.32        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -0.101350      -24.996620     91.7     nd       nd          nd            nd          0.22        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        3.244730       -26.243460     6.4      nd       nd          nd            nd          0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        3.244730       -26.243460     11.3     nd       nd          nd            nd          0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        3.244730       -26.243460     21.6     nd       nd          nd            nd          0.16        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        3.244730       -26.243460     48.8     nd       nd          nd            nd          0.14        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        3.244730       -26.243460     74.8     nd       nd          nd            nd          0.23        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        7.288970       -27.781710     8        nd       nd          nd            nd          0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        7.288970       -27.781710     15       nd       nd          nd            nd          0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        7.288970       -27.781710     25.9     nd       nd          nd            nd          0.13        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        7.288970       -27.781710     59.8     nd       nd          nd            nd          0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        7.288970       -27.781710     75.5     nd       nd          nd            nd          0.28        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        11.400530      -29.367860     18.5     nd       nd          nd            nd          0.14        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        11.400530      -29.367860     33.8     nd       nd          nd            nd          0.14        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        11.400530      -29.367860     79.9     nd       nd          nd            nd          0.18        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        14.755530      -30.683090     13       nd       nd          nd            nd          0.16        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        14.755530      -30.683090     24.4     nd       nd          nd            nd          0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        14.755530      -30.683090     44       nd       nd          nd            nd          0.19        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        14.755530      -30.683090     100.2    nd       nd          nd            nd          0.13        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        14.755530      -30.683090     150.5    nd       nd          nd            nd          0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        18.796360      -32.288790     15.6     nd       nd          nd            nd          0.17        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        18.796360      -32.288790     29.9     nd       nd          nd            nd          0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        18.796360      -32.288790     53.4     nd       nd          nd            nd          0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        18.796360      -32.288790     187.8    nd       nd          nd            nd          0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        22.334560      -33.733470     14.6     nd       nd          nd            nd          0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        22.334560      -33.733470     27.9     nd       nd          nd            nd          0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        22.334560      -33.733470     49.5     nd       nd          nd            nd          0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        22.334560      -33.733470     114.5    nd       nd          nd            nd          0.11        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        22.334560      -33.733470     172      nd       nd          nd            nd          0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        25.921990      -35.236290     16.9     nd       nd          nd            nd          0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        25.921990      -35.236290     31.1     nd       nd          nd            nd          0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        25.921990      -35.236290     56       nd       nd          nd            nd          0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        25.921990      -35.236290     129.9    nd       nd          nd            nd          0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        25.921990      -35.236290     195.2    nd       nd          nd            nd          0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        29.300540      -36.699450     17.1     nd       nd          nd            nd          0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        29.300540      -36.699450     31.6     nd       nd          nd            nd          0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        29.300540      -36.699450     56.2     nd       nd          nd            nd          0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        29.300540      -36.699450     130.4    nd       nd          nd            nd          0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        29.300540      -36.699450     195.9    nd       nd          nd            nd          0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        31.931150      -31.176350     99.3     nd       nd          nd            nd          0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        31.931150      -31.176350     179.2    nd       nd          nd            nd          0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.747000      -22.851630     10.2     nd       nd          nd            nd          0.22        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.747000      -22.851630     19.3     nd       nd          nd            nd          0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.747000      -22.851630     34.9     nd       nd          nd            nd          0.24        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.747000      -22.851630     89.3     nd       nd          nd            nd          0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.747000      -22.851630     129.5    nd       nd          nd            nd          0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        38.666340      -19.960590     12.8     nd       nd          nd            nd          0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        38.666340      -19.960590     24       nd       nd          nd            nd          0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        38.666340      -19.960590     49.8     nd       nd          nd            nd          0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        38.666340      -19.960590     80.6     nd       nd          nd            nd          0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        41.986230      -18.792650     7.7      nd       nd          nd            nd          0.22        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        41.986230      -18.792650     20.8     nd       nd          nd            nd          0.14        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        41.986230      -18.792650     36.7     nd       nd          nd            nd          0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        41.986230      -18.792650     71.1     nd       nd          nd            nd          0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        47.811410      -16.776940     9.8      nd       nd          nd            nd          0.17        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        47.811410      -16.776940     22.7     nd       nd          nd            nd          0.11        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        47.811410      -16.776940     43.2     nd       nd          nd            nd          0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        48.999860      -16.394740     7.8      nd       nd          nd            nd          0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        48.999860      -16.394740     15       nd       nd          nd            nd          0.13        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        48.999860      -16.394740     27.4     nd       nd          nd            nd          0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        48.999860      -16.394740     61.1     nd       nd          nd            nd          0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        48.999860      -16.394740     91.2     nd       nd          nd            nd          0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        47.923360      -14.610000     12.4     nd       nd          nd            nd          0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        47.923360      -14.610000     35.9     nd       nd          nd            nd          0.55        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        45.981980      -18.394110     27.3     nd       nd          nd            nd          0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        42.558280      -19.835600     11.8     nd       nd          nd            nd          0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        42.558280      -19.835600     16.9     nd       nd          nd            nd          0.23        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        42.558280      -19.835600     31.6     nd       nd          nd            nd          0.20        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        42.558280      -19.835600     51.7     nd       nd          nd            nd          0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.094710      -20.847100     16.9     nd       nd          nd            nd          0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.094710      -20.847100     26.3     nd       nd          nd            nd          0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.094710      -20.847100     52       nd       nd          nd            nd          0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.094710      -20.847100     87.4     nd       nd          nd            nd          0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.094710      -20.847100     151.6    nd       nd          nd            nd          0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        31.257880      -20.720070     16.6     nd       nd          nd            nd          0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        31.257880      -20.720070     117      nd       nd          nd            nd          0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        29.123730      -16.969410     15.5     nd       nd          nd            nd          0.11        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        29.123730      -16.969410     30.1     nd       nd          nd            nd          0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        29.123730      -16.969410     56.1     nd       nd          nd            nd          0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        29.123730      -16.969410     116.8    nd       nd          nd            nd          0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        29.123730      -16.969410     180.6    nd       nd          nd            nd          0.11        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        23.557630      -19.992710     11.6     nd       nd          nd            nd          0.18        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        23.557630      -19.992710     16.1     nd       nd          nd            nd          0.17        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        23.557630      -19.992710     26.3     nd       nd          nd            nd          0.17        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        23.557630      -19.992710     51.2     nd       nd          nd            nd          0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        23.557630      -19.992710     73.2     nd       nd          nd            nd          0.11        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        21.376780      -18.835470     4.5      nd       nd          nd            nd          0.20        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        21.376780      -18.835470     7.7      nd       nd          nd            nd          0.21        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        21.376780      -18.835470     17.3     nd       nd          nd            nd          0.21        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        21.376780      -18.835470     32.3     nd       nd          nd            nd          0.21        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        21.376780      -18.835470     52.5     nd       nd          nd            nd          0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        21.693600      -17.827200     26.8     nd       nd          nd            nd          0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        21.354650      -17.372570     7        nd       nd          nd            nd          0.58        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        21.354650      -17.372570     11.9     nd       nd          nd            nd          0.30        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        21.354650      -17.372570     17.1     nd       nd          nd            nd          0.14        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        21.307350      -18.593190     21.7     nd       nd          nd            nd          0.36        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        21.307350      -18.593190     31.7     nd       nd          nd            nd          0.14        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        17.838220      -20.891450     11.2     nd       nd          nd            nd          0.20        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        17.838220      -20.891450     30.3     nd       nd          nd            nd          0.20        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        17.838220      -20.891450     70.5     nd       nd          nd            nd          0.24        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        17.838220      -20.891450     101.3    nd       nd          nd            nd          0.13        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        14.295840      -21.759900     1.9      nd       nd          nd            nd          0.18        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        14.295840      -21.759900     10.7     nd       nd          nd            nd          0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        14.295840      -21.759900     50.9     nd       nd          nd            nd          0.19        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        14.295840      -21.759900     75.9     nd       nd          nd            nd          0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        11.001870      -22.514560     11.4     nd       nd          nd            nd          0.17        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        11.001870      -22.514560     17.2     nd       nd          nd            nd          0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        11.001870      -22.514560     26.3     nd       nd          nd            nd          0.16        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        11.001870      -22.514560     62.1     nd       nd          nd            nd          0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        7.861310       -23.231390     12.3     nd       nd          nd            nd          0.16        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        7.861310       -23.231390     16.5     nd       nd          nd            nd          0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        7.861310       -23.231390     26.2     nd       nd          nd            nd          0.14        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        7.861310       -23.231390     61.2     nd       nd          nd            nd          0.26        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        7.861310       -23.231390     81.5     nd       nd          nd            nd          0.16        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        4.765790       -23.908810     11.5     nd       nd          nd            nd          0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        4.765790       -23.908810     21       nd       nd          nd            nd          0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        4.765790       -23.908810     74.9     nd       nd          nd            nd          0.29        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        4.765790       -23.908810     110.4    nd       nd          nd            nd          0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        2.510220       -24.435000     12       nd       nd          nd            nd          0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        2.510220       -24.435000     22.4     nd       nd          nd            nd          0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        2.510220       -24.435000     31.4     nd       nd          nd            nd          0.14        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        2.510220       -24.435000     75       nd       nd          nd            nd          0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        0.067840       -24.973740     10.4     nd       nd          nd            nd          0.16        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        0.067840       -24.973740     15.5     nd       nd          nd            nd          0.17        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        0.067840       -24.973740     65.7     nd       nd          nd            nd          0.23        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        0.067840       -24.973740     99.8     nd       nd          nd            nd          0.21        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -6.846700      -25.012790     47.8     nd       nd          nd            nd          0.19        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -6.846700      -25.012790     101.2    nd       nd          nd            nd          0.02        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -10.408470     -24.992970     31.1     nd       nd          nd            nd          0.17        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -10.408470     -24.992970     56.3     nd       nd          nd            nd          0.10        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -10.408470     -24.992970     181.3    nd       nd          nd            nd          0.10        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -14.176930     -24.990500     21.3     nd       nd          nd            nd          0.09        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -14.176930     -24.990500     36.3     nd       nd          nd            nd          0.15        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -14.176930     -24.990500     61.3     nd       nd          nd            nd          0.14        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -14.176930     -24.990500     141.1    nd       nd          nd            nd          0.04        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -14.176930     -24.990500     201.4    nd       nd          nd            nd          0.04        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -17.948190     -24.994750     26.9     nd       nd          nd            nd          0.17        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -17.948190     -24.994750     46.2     nd       nd          nd            nd          0.15        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -17.948190     -24.994750     81.3     nd       nd          nd            nd          0.14        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -17.948190     -24.994750     174      nd       nd          nd            nd          0.11        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -17.948190     -24.994750     253.2    nd       nd          nd            nd          0.06        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -20.637160     -23.668980     24.2     nd       nd          nd            nd          0.16        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -20.637160     -23.668980     44.4     nd       nd          nd            nd          0.16        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -20.637160     -23.668980     79.6     nd       nd          nd            nd          0.16        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -20.637160     -23.668980     169.5    nd       nd          nd            nd          0.16        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -23.561620     -17.498310     88       nd       nd          nd            nd          0.06        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -23.561620     -17.498310     182.5    nd       nd          nd            nd          0.02        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -23.561620     -17.498310     278      nd       nd          nd            nd          0.02        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -25.234090     -13.911230     22.1     nd       nd          nd            nd          0.12        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -25.234090     -13.911230     41.7     nd       nd          nd            nd          0.16        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -25.234090     -13.911230     71.4     nd       nd          nd            nd          0.13        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -25.234090     -13.911230     150.4    nd       nd          nd            nd          0.11        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -25.234090     -13.911230     202.1    nd       nd          nd            nd          0.08        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -26.877630     -10.332840     22.5     nd       nd          nd            nd          0.14        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -26.877630     -10.332840     37.1     nd       nd          nd            nd          0.13        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -26.877630     -10.332840     62.2     nd       nd          nd            nd          0.13        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -26.877630     -10.332840     151.7    nd       nd          nd            nd          0.09        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -26.877630     -10.332840     221.8    nd       nd          nd            nd          0.04        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -28.580190     -6.568480      17.4     nd       nd          nd            nd          0.15        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -28.580190     -6.568480      26.6     nd       nd          nd            nd          0.11        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -28.580190     -6.568480      51.9     nd       nd          nd            nd          0.14        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -28.580190     -6.568480      112.4    nd       nd          nd            nd          0.11        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -28.580190     -6.568480      161.7    nd       nd          nd            nd          0.02        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -34.521730     -1.374660      36.7     nd       nd          nd            nd          0.09        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -34.521730     -1.374660      86.3     nd       nd          nd            nd          0.11        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -34.521730     -1.374660      121.9    nd       nd          nd            nd          0.08        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -37.833340     1.234340       6.9      nd       nd          nd            nd          0.14        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -37.833340     1.234340       12.7     nd       nd          nd            nd          0.17        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -37.833340     1.234340       22.8     nd       nd          nd            nd          0.16        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -37.833340     1.234340       43       nd       nd          nd            nd          0.16        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -37.833340     1.234340       73.2     nd       nd          nd            nd          0.10        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        -40.002730     5.015060       12.1     nd       nd          nd            nd          0.07        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        -40.002730     5.015060       21.8     nd       nd          nd            nd          0.05        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        -40.002730     5.015060       46.7     nd       nd          nd            nd          0.07        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        46.229740      -17.442120     2        nd       nd          nd            nd          0.30        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        46.229740      -17.442120     14.9     nd       nd          nd            nd          0.26        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        46.229740      -17.442120     26.8     nd       nd          nd            nd          0.25        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        46.229740      -17.442120     48.9     nd       nd          nd            nd          0.22        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        46.229740      -17.442120     57.5     nd       nd          nd            nd          0.18        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        46.229740      -17.442120     71.4     nd       nd          nd            nd          0.17        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        46.229740      -17.442120     110.9    nd       nd          nd            nd          0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        46.229740      -17.442120     165.5    nd       nd          nd            nd          0.14        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        46.229740      -17.442120     201      nd       nd          nd            nd          0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        46.229740      -17.442120     302.8    nd       nd          nd            nd          0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        44.347350      -19.333070     1.2      nd       nd          nd            nd          0.34        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        44.347350      -19.333070     4.8      nd       nd          nd            nd          0.31        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        44.347350      -19.333070     10.6     nd       nd          nd            nd          0.27        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        44.347350      -19.333070     20       nd       nd          nd            nd          0.26        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        44.347350      -19.333070     40.2     nd       nd          nd            nd          0.26        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        44.347350      -19.333070     45.3     nd       nd          nd            nd          0.25        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        44.347350      -19.333070     46.9     nd       nd          nd            nd          0.19        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        44.347350      -19.333070     58.2     nd       nd          nd            nd          0.18        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        44.347350      -19.333070     70.3     nd       nd          nd            nd          0.14        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        44.347350      -19.333070     98.1     nd       nd          nd            nd          0.11        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        44.347350      -19.333070     198.2    nd       nd          nd            nd          0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        44.347350      -19.333070     299.2    nd       nd          nd            nd          0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        35.922540      -29.130920     12.2     nd       nd          nd            nd          0.20        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        35.922540      -29.130920     22.9     nd       nd          nd            nd          0.18        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        35.922540      -29.130920     40.9     nd       nd          nd            nd          0.16        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        35.922540      -29.130920     79.9     nd       nd          nd            nd          0.13        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        35.922540      -29.130920     84.6     nd       nd          nd            nd          0.11        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        35.922540      -29.130920     104.1    nd       nd          nd            nd          0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        35.922540      -29.130920     141      nd       nd          nd            nd          0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        35.922540      -29.130920     201      nd       nd          nd            nd          0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        35.922540      -29.130920     300.1    nd       nd          nd            nd          0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        31.299680      -32.048180     23.3     nd       nd          nd            nd          0.24        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        31.299680      -32.048180     43.4     nd       nd          nd            nd          0.20        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        31.299680      -32.048180     68.6     nd       nd          nd            nd          0.18        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        31.299680      -32.048180     78.9     nd       nd          nd            nd          0.16        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        31.299680      -32.048180     88.9     nd       nd          nd            nd          0.14        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        31.299680      -32.048180     99.7     nd       nd          nd            nd          0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        31.299680      -32.048180     117.6    nd       nd          nd            nd          0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        31.299680      -32.048180     149.3    nd       nd          nd            nd          0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        31.299680      -32.048180     198.5    nd       nd          nd            nd          0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        31.299680      -32.048180     298.7    nd       nd          nd            nd          0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        29.526110      -36.273220     13.1     nd       nd          nd            nd          0.26        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        29.526110      -36.273220     23.4     nd       nd          nd            nd          0.25        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        29.526110      -36.273220     44       nd       nd          nd            nd          0.25        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        29.526110      -36.273220     79.6     nd       nd          nd            nd          0.21        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        29.526110      -36.273220     91       nd       nd          nd            nd          0.19        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        29.526110      -36.273220     100.1    nd       nd          nd            nd          0.17        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        29.526110      -36.273220     120      nd       nd          nd            nd          0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        29.526110      -36.273220     151.8    nd       nd          nd            nd          0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        29.526110      -36.273220     201.3    nd       nd          nd            nd          0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling 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        29.526110      -36.273220     300.6    nd       nd          nd            nd          0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        27.781940      -38.808050     15.5     nd       nd          nd            nd          0.26        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        27.781940      -38.808050     28.8     nd       nd          nd            nd          0.26        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        27.781940      -38.808050     50.9     nd       nd          nd            nd          0.23        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        27.781940      -38.808050     101.1    nd       nd          nd            nd          0.21        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        27.781940      -38.808050     111.1    nd       nd          nd            nd          0.21        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        27.781940      -38.808050     115.9    nd       nd          nd            nd          0.18        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        27.781940      -38.808050     125.7    nd       nd          nd            nd          0.16        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        27.781940      -38.808050     174      nd       nd          nd            nd          0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        27.781940      -38.808050     201.5    nd       nd          nd            nd          0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        27.781940      -38.808050     300.6    nd       nd          nd            nd          0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        23.961980      -36.778570     26.9     nd       nd          nd            nd          0.18        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        23.961980      -36.778570     47.9     nd       nd          nd            nd          0.19        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        23.961980      -36.778570     85.7     nd       nd          nd            nd          0.17        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        23.961980      -36.778570     96       nd       nd          nd            nd          0.16        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        23.961980      -36.778570     100.8    nd       nd          nd            nd          0.14        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        23.961980      -36.778570     105.7    nd       nd          nd            nd          0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        23.961980      -36.778570     114      nd       nd          nd            nd          0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        23.961980      -36.778570     161.6    nd       nd          nd            nd          0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        23.961980      -36.778570     202.1    nd       nd          nd            nd          0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        23.961980      -36.778570     300.8    nd       nd          nd            nd          0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        21.053510      -35.272660     17.9     nd       nd          nd            nd          0.20        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        21.053510      -35.272660     30.9     nd       nd          nd            nd          0.19        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        21.053510      -35.272660     57.8     nd       nd          nd            nd          0.19        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        21.053510      -35.272660     91.8     nd       nd          nd            nd          0.18        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        21.053510      -35.272660     110.3    nd       nd          nd            nd          0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        21.053510      -35.272660     120.5    nd       nd          nd            nd          0.16        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        21.053510      -35.272660     127.1    nd       nd          nd            nd          0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        21.053510      -35.272660     135.7    nd       nd          nd            nd          0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        21.053510      -35.272660     195.2    nd       nd          nd            nd          0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        21.053510      -35.272660     300.6    nd       nd          nd            nd          0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        18.377980      -33.914540     15.9     nd       nd          nd            nd          0.17        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        18.377980      -33.914540     53.3     nd       nd          nd            nd          0.17        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        18.377980      -33.914540     89.5     nd       nd          nd            nd          0.17        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        18.377980      -33.914540     98.7     nd       nd          nd            nd          0.17        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        18.377980      -33.914540     110.3    nd       nd          nd            nd          0.16        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        18.377980      -33.914540     114.1    nd       nd          nd            nd          0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        18.377980      -33.914540     129.1    nd       nd          nd            nd          0.13        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        18.377980      -33.914540     184.7    nd       nd          nd            nd          0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        18.377980      -33.914540     297.4    nd       nd          nd            nd          0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        15.125220      -32.296400     1.4      nd       nd          nd            nd          0.21        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        15.125220      -32.296400     11.2     nd       nd          nd            nd          0.20        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        15.125220      -32.296400     20.1     nd       nd          nd            nd          0.18        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        15.125220      -32.296400     37       nd       nd          nd            nd          0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        15.125220      -32.296400     70.6     nd       nd          nd            nd          0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        15.125220      -32.296400     81.3     nd       nd          nd            nd          0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        15.125220      -32.296400     84.5     nd       nd          nd            nd          0.11        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        15.125220      -32.296400     90.9     nd       nd          nd            nd          0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        15.125220      -32.296400     126.3    nd       nd          nd            nd          0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        15.125220      -32.296400     199.8    nd       nd          nd            nd          0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        15.125220      -32.296400     298.8    nd       nd          nd            nd          0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        12.069690      -30.802510     3.8      nd       nd          nd            nd          0.16        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        12.069690      -30.802510     8.4      nd       nd          nd            nd          0.16        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        12.069690      -30.802510     16.8     nd       nd          nd            nd          0.14        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        12.069690      -30.802510     29.5     nd       nd          nd            nd          0.11        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        12.069690      -30.802510     34.6     nd       nd          nd            nd          0.14        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        12.069690      -30.802510     40.2     nd       nd          nd            nd          0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        12.069690      -30.802510     44.9     nd       nd          nd            nd          0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        12.069690      -30.802510     60.2     nd       nd          nd            nd          0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        12.069690      -30.802510     100.2    nd       nd          nd            nd          0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        12.069690      -30.802510     200      nd       nd          nd            nd          0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        12.069690      -30.802510     300.7    nd       nd          nd            nd          0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        9.433970       -29.520060     7.5      nd       nd          nd            nd          0.26        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        9.433970       -29.520060     14       nd       nd          nd            nd          0.25        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        9.433970       -29.520060     25.6     nd       nd          nd            nd          0.20        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        9.433970       -29.520060     48.5     nd       nd          nd            nd          0.18        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        9.433970       -29.520060     58.3     nd       nd          nd            nd          0.16        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        9.433970       -29.520060     59.2     nd       nd          nd            nd          0.14        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        9.433970       -29.520060     68.5     nd       nd          nd            nd          0.13        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        9.433970       -29.520060     88.5     nd       nd          nd            nd          0.11        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        9.433970       -29.520060     198.3    nd       nd          nd            nd          0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        9.433970       -29.520060     298.3    nd       nd          nd            nd          0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        6.506560       -28.110060     4.7      nd       nd          nd            nd          0.24        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        6.506560       -28.110060     11.6     nd       nd          nd            nd          0.19        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        6.506560       -28.110060     20.8     nd       nd          nd            nd          0.19        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        6.506560       -28.110060     39.9     nd       nd          nd            nd          0.16        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        6.506560       -28.110060     43.5     nd       nd          nd            nd          0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        6.506560       -28.110060     47       nd       nd          nd            nd          0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        6.506560       -28.110060     59.8     nd       nd          nd            nd          0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        6.506560       -28.110060     71.8     nd       nd          nd            nd          0.11        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        6.506560       -28.110060     200.5    nd       nd          nd            nd          0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        6.506560       -28.110060     299.7    nd       nd          nd            nd          0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        3.476400       -26.659920     9.9      nd       nd          nd            nd          0.28        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        3.476400       -26.659920     18.8     nd       nd          nd            nd          0.26        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        3.476400       -26.659920     34       nd       nd          nd            nd          0.24        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        3.476400       -26.659920     54.5     nd       nd          nd            nd          0.20        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        3.476400       -26.659920     73.4     nd       nd          nd            nd          0.18        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        3.476400       -26.659920     77.5     nd       nd          nd            nd          0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        3.476400       -26.659920     80.8     nd       nd          nd            nd          0.17        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        3.476400       -26.659920     89.2     nd       nd          nd            nd          0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        3.476400       -26.659920     116.7    nd       nd          nd            nd          0.11        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        3.476400       -26.659920     198.8    nd       nd          nd            nd          0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        3.476400       -26.659920     297.6    nd       nd          nd            nd          0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        0.892270       -25.435760     11       nd       nd          nd            nd          0.26        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        0.892270       -25.435760     20.1     nd       nd          nd            nd          0.23        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        0.892270       -25.435760     69.1     nd       nd          nd            nd          0.19        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        0.892270       -25.435760     77.5     nd       nd          nd            nd          0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        0.892270       -25.435760     81.4     nd       nd          nd            nd          0.11        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        0.892270       -25.435760     94.4     nd       nd          nd            nd          0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        0.892270       -25.435760     128.4    nd       nd          nd            nd          0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        0.892270       -25.435760     199.8    nd       nd          nd            nd          0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        0.892270       -25.435760     299      nd       nd          nd            nd          0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -2.887930      -24.998910     10.2     nd       nd          nd            nd          0.25        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -2.887930      -24.998910     19.2     nd       nd          nd            nd          0.23        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -2.887930      -24.998910     34.1     nd       nd          nd            nd          0.20        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -2.887930      -24.998910     78.7     nd       nd          nd            nd          0.17        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -2.887930      -24.998910     83.3     nd       nd          nd            nd          0.14        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -2.887930      -24.998910     87.2     nd       nd          nd            nd          0.12        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -2.887930      -24.998910     119.5    nd       nd          nd            nd          0.10        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -2.887930      -24.998910     201.3    nd       nd          nd            nd          0.08        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -2.887930      -24.998910     300.1    nd       nd          nd            nd          0.05        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -8.276090      -24.995770     2.4      nd       nd          nd            nd          0.30        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -8.276090      -24.995770     14.3     nd       nd          nd            nd          0.30        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -8.276090      -24.995770     25.7     nd       nd          nd            nd          0.20        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -8.276090      -24.995770     45.5     nd       nd          nd            nd          0.20        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -8.276090      -24.995770     60.9     nd       nd          nd            nd          0.18        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -8.276090      -24.995770     70.6     nd       nd          nd            nd          0.16        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -8.276090      -24.995770     85.6     nd       nd          nd            nd          0.15        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -8.276090      -24.995770     92.3     nd       nd          nd            nd          0.14        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -8.276090      -24.995770     98.8     nd       nd          nd            nd          0.11        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -8.276090      -24.995770     103.6    nd       nd          nd            nd          0.11        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -8.276090      -24.995770     110.2    nd       nd          nd            nd          0.08        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -8.276090      -24.995770     120.3    nd       nd          nd            nd          0.05        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -8.276090      -24.995770     129.6    nd       nd          nd            nd          0.04        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -8.276090      -24.995770     156.9    nd       nd          nd            nd          0.04        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -8.276090      -24.995770     199.6    nd       nd          nd            nd          0.03        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -8.276090      -24.995770     300.1    nd       nd          nd            nd          0.03        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -11.000240     -24.999220     17.9     nd       nd          nd            nd          0.28        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -11.000240     -24.999220     31.5     nd       nd          nd            nd          0.26        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -11.000240     -24.999220     57.7     nd       nd          nd            nd          0.24        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -11.000240     -24.999220     110.3    nd       nd          nd            nd          0.19        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -11.000240     -24.999220     123.9    nd       nd          nd            nd          0.21        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -11.000240     -24.999220     128.4    nd       nd          nd            nd          0.16        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -11.000240     -24.999220     136.5    nd       nd          nd            nd          0.14        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -11.000240     -24.999220     140.9    nd       nd          nd            nd          0.12        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -11.000240     -24.999220     150.2    nd       nd          nd            nd          0.10        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -11.000240     -24.999220     195.6    nd       nd          nd            nd          0.08        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -11.000240     -24.999220     300.4    nd       nd          nd            nd          0.05        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -14.380670     -24.996580     1.9      nd       nd          nd            nd          0.31        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -14.380670     -24.996580     19       nd       nd          nd            nd          0.28        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -14.380670     -24.996580     35.2     nd       nd          nd            nd          0.28        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -14.380670     -24.996580     63.9     nd       nd          nd            nd          0.27        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -14.380670     -24.996580     99.8     nd       nd          nd            nd          0.20        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -14.380670     -24.996580     139.1    nd       nd          nd            nd          0.18        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -14.380670     -24.996580     146.6    nd       nd          nd            nd          0.16        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -14.380670     -24.996580     149.7    nd       nd          nd            nd          0.10        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -14.380670     -24.996580     159.5    nd       nd          nd            nd          0.08        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -14.380670     -24.996580     221      nd       nd          nd            nd          0.06        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -14.380670     -24.996580     300.8    nd       nd          nd            nd          0.04        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -18.559740     -24.999190     2.1      nd       nd          nd            nd          0.28        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -18.559740     -24.999190     21.7     nd       nd          nd            nd          0.26        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -18.559740     -24.999190     39.5     nd       nd          nd            nd          0.24        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -18.559740     -24.999190     71.7     nd       nd          nd            nd          0.19        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -18.559740     -24.999190     139      nd       nd          nd            nd          0.18        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -18.559740     -24.999190     155.2    nd       nd          nd            nd          0.15        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -18.559740     -24.999190     165.9    nd       nd          nd            nd          0.12        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -18.559740     -24.999190     174.5    nd       nd          nd            nd          0.09        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -18.559740     -24.999190     179.1    nd       nd          nd            nd          0.10        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -18.559740     -24.999190     300.6    nd       nd          nd            nd          0.07        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -21.129280     -22.438990     1.8      nd       nd          nd            nd          0.27        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -21.129280     -22.438990     18       nd       nd          nd            nd          0.24        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -21.129280     -22.438990     33.1     nd       nd          nd            nd          0.20        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -21.129280     -22.438990     60.1     nd       nd          nd            nd          0.18        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -21.129280     -22.438990     115.1    nd       nd          nd            nd          0.13        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -21.129280     -22.438990     127.9    nd       nd          nd            nd          0.11        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -21.129280     -22.438990     138.7    nd       nd          nd            nd          0.10        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -21.129280     -22.438990     144.7    nd       nd          nd            nd          0.08        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -21.129280     -22.438990     152.4    nd       nd          nd            nd          0.03        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -21.129280     -22.438990     209      nd       nd          nd            nd          0.03        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -21.129280     -22.438990     300.3    nd       nd          nd            nd          0.03        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -21.103350     -22.378680     41.2     nd       nd          nd            nd          0.20        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -21.103350     -22.378680     75.2     nd       nd          nd            nd          0.19        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -21.103350     -22.378680     129.8    nd       nd          nd            nd          0.18        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -21.103350     -22.378680     159.7    nd       nd          nd            nd          0.15        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -21.103350     -22.378680     170      nd       nd          nd            nd          0.13        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -21.103350     -22.378680     173.7    nd       nd          nd            nd          0.08        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -21.103350     -22.378680     179.1    nd       nd          nd            nd          0.06        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -21.103350     -22.378680     200.7    nd       nd          nd            nd          0.10        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -21.103350     -22.378680     272.1    nd       nd          nd            nd          0.07        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -22.142940     -20.198630     1.4      nd       nd          nd            nd          0.28        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -22.142940     -20.198630     19.9     nd       nd          nd            nd          0.25        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -22.142940     -20.198630     35.6     nd       nd          nd            nd          0.20        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -22.142940     -20.198630     64.5     nd       nd          nd            nd          0.16        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -22.142940     -20.198630     128.7    nd       nd          nd            nd          0.10        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -22.142940     -20.198630     139.1    nd       nd          nd            nd          0.08        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -22.142940     -20.198630     164.6    nd       nd          nd            nd          0.05        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -22.142940     -20.198630     179.2    nd       nd          nd            nd          0.04        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -22.142940     -20.198630     225      nd       nd          nd            nd          0.03        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -22.142940     -20.198630     299.9    nd       nd          nd            nd          0.03        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -23.763010     -16.527360     1.5      nd       nd          nd            nd          0.29        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -23.763010     -16.527360     39.1     nd       nd          nd            nd          0.24        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -23.763010     -16.527360     70.6     nd       nd          nd            nd          0.19        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -23.763010     -16.527360     149.9    nd       nd          nd            nd          0.12        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -23.763010     -16.527360     159.9    nd       nd          nd            nd          0.10        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -23.763010     -16.527360     163.6    nd       nd          nd            nd          0.04        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -23.763010     -16.527360     170.1    nd       nd          nd            nd          0.05        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -23.763010     -16.527360     175      nd       nd          nd            nd          0.04        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -23.763010     -16.527360     245.9    nd       nd          nd            nd          0.04        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -23.763010     -16.527360     300.4    nd       nd          nd            nd          0.03        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -26.140920     -11.057220     18.5     nd       nd          nd            nd          0.21        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -26.140920     -11.057220     31.4     nd       nd          nd            nd          0.24        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -26.140920     -11.057220     56.3     nd       nd          nd            nd          0.23        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -26.140920     -11.057220     81.1     nd       nd          nd            nd          0.21        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -26.140920     -11.057220     101.1    nd       nd          nd            nd          0.20        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -26.140920     -11.057220     116.2    nd       nd          nd            nd          0.18        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -26.140920     -11.057220     128.2    nd       nd          nd            nd          0.18        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -26.140920     -11.057220     135.2    nd       nd          nd            nd          0.14        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -26.140920     -11.057220     150.8    nd       nd          nd            nd          0.12        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -26.140920     -11.057220     170.7    nd       nd          nd            nd          0.09        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -26.140920     -11.057220     191      nd       nd          nd            nd          0.07        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -26.140920     -11.057220     201.5    nd       nd          nd            nd          0.06        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -26.140920     -11.057220     299.4    nd       nd          nd            nd          0.04        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -27.396770     -8.116730      2        nd       nd          nd            nd          0.24        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -27.396770     -8.116730      13.1     nd       nd          nd            nd          0.21        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -27.396770     -8.116730      23.4     nd       nd          nd            nd          0.19        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -27.396770     -8.116730      43.3     nd       nd          nd            nd          0.17        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -27.396770     -8.116730      85       nd       nd          nd            nd          0.14        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -27.396770     -8.116730      93.9     nd       nd          nd            nd          0.14        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -27.396770     -8.116730      97.7     nd       nd          nd            nd          0.15        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -27.396770     -8.116730      103.2    nd       nd          nd            nd          0.12        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -27.396770     -8.116730      112.7    nd       nd          nd            nd          0.10        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -27.396770     -8.116730      147.5    nd       nd          nd            nd          0.10        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -27.396770     -8.116730      200.3    nd       nd          nd            nd          0.08        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -27.396770     -8.116730      300.8    nd       nd          nd            nd          0.05        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -28.854460     -4.688110      1.3      nd       nd          nd            nd          0.25        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -28.854460     -4.688110      17       nd       nd          nd            nd          0.24        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -28.854460     -4.688110      31.1     nd       nd          nd            nd          0.20        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -28.854460     -4.688110      56.1     nd       nd          nd            nd          0.18        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -28.854460     -4.688110      109.6    nd       nd          nd            nd          0.10        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -28.854460     -4.688110      121.4    nd       nd          nd            nd          0.14        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -28.854460     -4.688110      128      nd       nd          nd            nd          0.09        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -28.854460     -4.688110      133.6    nd       nd          nd            nd          0.10        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -28.854460     -4.688110      149.5    nd       nd          nd            nd          0.10        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -28.854460     -4.688110      190.8    nd       nd          nd            nd          0.09        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -28.854460     -4.688110      299.4    nd       nd          nd            nd          0.07        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -30.673180     -0.299800      8.1      nd       nd          nd            nd          0.26        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -30.673180     -0.299800      15.4     nd       nd          nd            nd          0.27        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -30.673180     -0.299800      28.4     nd       nd          nd            nd          0.25        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -30.673180     -0.299800      46.8     nd       nd          nd            nd          0.21        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -30.673180     -0.299800      55.4     nd       nd          nd            nd          0.20        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -30.673180     -0.299800      64       nd       nd          nd            nd          0.19        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -30.673180     -0.299800      70.3     nd       nd          nd            nd          0.16        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -30.673180     -0.299800      74.9     nd       nd          nd            nd          0.13        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -30.673180     -0.299800      96.1     nd       nd          nd            nd          0.11        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -30.673180     -0.299800      199.7    nd       nd          nd            nd          0.09        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -30.673180     -0.299800      299.5    nd       nd          nd            nd          0.05        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -32.527980     4.236090       1.8      nd       nd          nd            nd          0.29        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -32.527980     4.236090       8.1      nd       nd          nd            nd          0.27        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -32.527980     4.236090       15       nd       nd          nd            nd          0.24        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -32.527980     4.236090       55.3     nd       nd          nd            nd          0.18        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -32.527980     4.236090       58.3     nd       nd          nd            nd          0.17        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -32.527980     4.236090       69.5     nd       nd          nd            nd          0.13        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -32.527980     4.236090       75       nd       nd          nd            nd          0.11        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -32.527980     4.236090       86.1     nd       nd          nd            nd          0.10        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -32.527980     4.236090       298.2    nd       nd          nd            nd          0.06        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -33.645810     8.915220       6.4      nd       nd          nd            nd          0.24        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -33.645810     8.915220       10       nd       nd          nd            nd          0.20        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -33.645810     8.915220       17.7     nd       nd          nd            nd          0.12        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -33.645810     8.915220       29.7     nd       nd          nd            nd          0.12        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -33.645810     8.915220       35.3     nd       nd          nd            nd          0.14        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -33.645810     8.915220       41.6     nd       nd          nd            nd          0.12        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -33.645810     8.915220       49.3     nd       nd          nd            nd          0.12        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -33.645810     8.915220       63.4     nd       nd          nd            nd          0.01        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -33.645810     8.915220       100.1    nd       nd          nd            nd          0.09        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -33.645810     8.915220       198.7    nd       nd          nd            nd          0.09        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -33.645810     8.915220       303.8    nd       nd          nd            nd          0.07        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -33.906760     10.303150      1.7      nd       nd          nd            nd          0.19        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -33.906760     10.303150      4.9      nd       nd          nd            nd          0.18        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -33.906760     10.303150      9.5      nd       nd          nd            nd          0.19        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -33.906760     10.303150      14.9     nd       nd          nd            nd          0.13        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -33.906760     10.303150      19.9     nd       nd          nd            nd          0.16        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -33.906760     10.303150      24.7     nd       nd          nd            nd          0.09        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -33.906760     10.303150      26.6     nd       nd          nd            nd          0.16        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -33.906760     10.303150      30.7     nd       nd          nd            nd          0.14        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -33.906760     10.303150      39.9     nd       nd          nd            nd          0.12        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -33.906760     10.303150      60.4     nd       nd          nd            nd          0.12        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -33.906760     10.303150      99.4     nd       nd          nd            nd          0.10        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. Phosphorus cycling in 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        -33.906760     10.303150      199      nd       nd          nd            nd          0.09        South Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.507500      -76.637500     11       nd       nd          0.00          0.00        0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.507500      -76.637500     11       nd       nd          0.00          0.00        0.22        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.507500      -76.637500     15       nd       nd          0.23          0.01        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.507500      -76.637500     55       nd       nd          0.10          0.00        0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.507500      -76.637500     201      nd       nd          0.93          0.04        0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.507500      -76.637500     388      nd       nd          5.32          0.25        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.507500      -76.637500     624      nd       nd          15.15         0.98        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.507500      -76.637500     1316     nd       nd          18.46         1.26        0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         26.507500      -76.637500     4687     nd       nd          20.28         1.44        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.502400      -75.910300     17       nd       nd          0.00          0.00        0.11        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.502400      -75.910300     57       nd       nd          0.00          0.00        0.11        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.502400      -75.910300     108      nd       nd          0.00          0.00        0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.502400      -75.910300     208      nd       nd          0.99          0.01        0.11        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.502400      -75.910300     309      nd       nd          2.80          0.09        0.14        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.502400      -75.910300     510      nd       nd          7.90          0.40        0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.502400      -75.910300     2029     nd       nd          19.50         1.17        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         26.502400      -75.910300     2639     nd       nd          19.20         1.24        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         26.502400      -75.910300     4819     nd       nd          23.10         1.42        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.491700      -75.703600     17       nd       nd          0.00          0.00        0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.491700      -75.703600     17       nd       nd          0.00          0.00        0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.515500      -75.074600     18       nd       nd          0.00          0.00        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.515500      -75.074600     58       nd       nd          0.00          0.00        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.515500      -75.074600     108      nd       nd          0.40          0.07        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.515500      -75.074600     208      nd       nd          1.70          0.04        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.515500      -75.074600     309      nd       nd          2.90          0.12        0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.515500      -75.074600     409      nd       nd          5.30          0.24        0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.515500      -75.074600     1116     nd       nd          21.80         1.41        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         26.515500      -75.074600     3246     nd       nd          18.60         1.22        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         26.515500      -75.074600     4167     nd       nd          20.20         1.28        0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.501200      -73.929900     17       nd       nd          0.10          0.04        0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.501200      -73.929900     57       nd       nd          0.10          0.04        0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.501200      -73.929900     108      nd       nd          0.10          0.04        0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.501200      -73.929900     208      nd       nd          1.00          0.07        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.501200      -73.929900     309      nd       nd          2.90          0.14        0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.501200      -73.929900     510      nd       nd          8.50          0.51        0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.501200      -73.929900     1116     nd       nd          21.20         1.50        0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         26.501200      -73.929900     3743     nd       nd          18.20         1.24        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.499600      -72.486000     19       nd       nd          0.08          0.03        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.499600      -72.486000     59       nd       nd          0.11          0.02        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.499600      -72.486000     110      nd       nd          0.07          0.03        0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.499600      -72.486000     210      nd       nd          0.70          0.05        0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.499600      -72.486000     361      nd       nd          3.70          0.17        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.499600      -72.486000     714      nd       nd          14.60         0.97        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.499600      -72.486000     1573     nd       nd          18.40         1.23        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.499600      -72.486000     2791     nd       nd          19.00         1.25        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         26.499600      -72.486000     4327     nd       nd          18.30         1.41        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         26.499600      -72.486000     5290     nd       nd          22.50         1.62        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.490000      -70.986700     20       nd       nd          0.10          0.05        0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.490000      -70.986700     59       nd       nd          0.10          0.02        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.490000      -70.986700     110      nd       nd          0.37          0.02        0.17        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.490000      -70.986700     211      nd       nd          2.20          0.08        0.13        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.490000      -70.986700     362      nd       nd          4.70          0.23        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.490000      -70.986700     512      nd       nd          7.80          0.45        0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.490000      -70.986700     2757     nd       nd          18.60         1.37        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        25.000800      -69.506200     59       nd       nd          0.10          0.06        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        25.000800      -69.506200     110      nd       nd          0.20          0.04        0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        25.000800      -69.506200     210      nd       nd          2.30          0.11        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        25.000800      -69.506200     511      nd       nd          9.59          0.60        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        25.000800      -69.506200     1601     nd       nd          17.01         1.33        0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        25.000800      -69.506200     2784     nd       nd          19.21         1.33        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         25.000800      -69.506200     3708     nd       nd          19.21         1.35        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         25.000800      -69.506200     5703     nd       nd          23.20         1.63        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.495800      -65.463500     19       nd       nd          0.10          0.00        0.14        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.495800      -65.463500     60       nd       nd          0.30          0.01        0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.495800      -65.463500     110      nd       nd          0.20          0.01        0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.495800      -65.463500     210      nd       nd          2.91          0.10        0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.495800      -65.463500     361      nd       nd          6.22          0.28        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.495800      -65.463500     512      nd       nd          9.00          0.58        0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.495800      -65.463500     714      nd       nd          19.90         1.33        0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.495800      -65.463500     1118     nd       nd          22.30         1.41        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         24.495800      -65.463500     5662     nd       nd          22.30         1.61        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.501200      -61.063000     21       nd       nd          0.10          0.00        0.13        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.501200      -61.063000     62       nd       nd          0.00          0.00        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.501200      -61.063000     163      nd       nd          0.80          0.01        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.501200      -61.063000     363      nd       nd          6.00          0.32        0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.501200      -61.063000     513      nd       nd          12.00         0.66        0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.501200      -61.063000     714      nd       nd          22.20         1.32        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.501200      -61.063000     2846     nd       nd          21.20         1.37        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         24.501200      -61.063000     4639     nd       nd          21.00         1.32        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.500000      -56.666500     22       nd       nd          0.00          0.00        0.20        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.500000      -56.666500     63       nd       nd          0.10          0.00        0.22        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.500000      -56.666500     113      nd       nd          0.10          0.01        0.18        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.500000      -56.666500     213      nd       nd          2.40          0.08        0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.500000      -56.666500     364      nd       nd          6.01          0.30        0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.500000      -56.666500     515      nd       nd          12.55         0.71        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.500000      -56.666500     1628     nd       nd          19.30         1.35        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.500000      -56.666500     2187     nd       nd          20.40         1.35        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.500000      -56.666500     2848     nd       nd          23.87         1.37        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         24.500000      -56.666500     6001     nd       nd          27.64         1.71        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.501300      -54.465300     20       nd       nd          0.00          0.00        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.501300      -54.465300     60       nd       nd          0.00          0.00        0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.501300      -54.465300     110      nd       nd          0.20          0.00        0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.501300      -54.465300     210      nd       nd          2.70          0.09        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.501300      -54.465300     360      nd       nd          6.40          0.30        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.501300      -54.465300     510      nd       nd          11.00         0.66        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.501300      -54.465300     711      nd       nd          20.80         1.31        0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.501300      -54.465300     913      nd       nd          25.30         1.73        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.501300      -54.465300     1316     nd       nd          20.00         1.34        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         24.501300      -54.465300     2945     nd       nd          20.90         1.41        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         24.501300      -54.465300     4785     nd       nd          23.10         1.55        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.499400      -52.161400     20       nd       nd          0.40          0.02        0.21        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.499400      -52.161400     60       nd       nd          0.00          0.01        0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.499400      -52.161400     111      nd       nd          0.10          0.01        0.21        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.499400      -52.161400     211      nd       nd          3.80          0.16        0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.499400      -52.161400     967      nd       nd          26.10         1.75        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.499400      -52.161400     1422     nd       nd          20.40         1.33        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.499400      -52.161400     2030     nd       nd          20.10         1.31        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         24.499400      -52.161400     2639     nd       nd          20.90         1.38        0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         24.499400      -52.161400     4481     nd       nd          22.27         1.53        0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.499500      -50.441700     19       nd       nd          0.20          0.04        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.499500      -50.441700     59       nd       nd          0.20          0.03        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.499500      -50.441700     110      nd       nd          0.20          0.04        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.499500      -50.441700     210      nd       nd          4.80          0.22        0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.499500      -50.441700     361      nd       nd          9.00          0.45        0.13        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.499500      -50.441700     714      nd       nd          23.40         1.45        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.499500      -50.441700     1119     nd       nd          24.20         1.54        0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.499500      -50.441700     1575     nd       nd          21.10         1.34        0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.499500      -50.441700     2081     nd       nd          21.10         1.37        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         24.499500      -50.441700     3099     nd       nd          21.40         1.46        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         24.499500      -50.441700     4122     nd       nd          22.30         1.47        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         24.499500      -50.441700     4792     nd       nd          20.28         1.59        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.505500      -47.962600     16       nd       nd          0.00          0.00        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.505500      -47.962600     56       nd       nd          0.00          0.00        0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.505500      -47.962600     107      nd       nd          0.10          0.00        0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.505500      -47.962600     207      nd       nd          2.50          0.11        0.25        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.505500      -47.962600     358      nd       nd          9.40          0.51        0.20        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.505500      -47.962600     509      nd       nd          14.40         0.84        0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.505500      -47.962600     712      nd       nd          20.90         1.30        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.505500      -47.962600     1014     nd       nd          27.20         1.79        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.505500      -47.962600     1824     nd       nd          20.60         1.35        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         24.505500      -47.962600     2638     nd       nd          21.20         1.41        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         24.505500      -47.962600     3453     nd       nd          21.90         1.45        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         24.505500      -47.962600     4010     nd       nd          22.00         1.51        0.16        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.504800      -45.490300     14       nd       nd          0.10          0.00        0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.504800      -45.490300     54       nd       nd          0.10          0.01        0.17        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.504800      -45.490300     105      nd       nd          0.10          0.00        0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.504800      -45.490300     205      nd       nd          1.30          0.03        0.11        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.504800      -45.490300     357      nd       nd          7.60          0.39        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.504800      -45.490300     1519     nd       nd          21.90         1.46        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.504800      -45.490300     1823     nd       nd          20.50         1.37        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         24.504800      -45.490300     2432     nd       nd          21.90         1.42        0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         24.504800      -45.490300     3466     nd       nd          22.70         1.50        0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.509700      -43.007200     18       nd       nd          0.10          0.00        0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.509700      -43.007200     58       nd       nd          0.10          0.01        0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.509700      -43.007200     108      nd       nd          0.10          0.00        0.13        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.509700      -43.007200     209      nd       nd          3.70          0.18        0.14        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.509700      -43.007200     359      nd       nd          9.70          0.56        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.509700      -43.007200     705      nd       nd          24.00         1.52        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.509700      -43.007200     1107     nd       nd          26.10         1.77        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         24.509700      -43.007200     3532     nd       nd          22.80         1.66        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         24.509700      -43.007200     4169     nd       nd          23.10         1.58        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.508700      -41.639900     19       nd       nd          0.10          0.00        0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.508700      -41.639900     60       nd       nd          0.00          0.00        0.16        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.508700      -41.639900     110      nd       nd          0.00          0.02        0.13        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.508700      -41.639900     210      nd       nd          3.70          0.16        0.14        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.508700      -41.639900     359      nd       nd          8.30          0.43        0.13        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.508700      -41.639900     508      nd       nd          13.70         0.77        0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.508700      -41.639900     1101     nd       nd          26.50         1.74        0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.508700      -41.639900     1495     nd       nd          22.80         1.49        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         24.508700      -41.639900     3024     nd       nd          22.20         1.48        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.500000      -38.513300     19       nd       nd          0.10          0.00        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.500000      -38.513300     60       nd       nd          0.10          0.00        0.31        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.500000      -38.513300     111      nd       nd          0.10          0.00        0.36        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.500000      -38.513300     1523     nd       nd          21.80         1.33        0.24        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.500000      -38.513300     2532     nd       nd          21.30         1.31        0.33        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         24.500000      -38.513300     3800     nd       nd          22.30         1.41        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.504500      -35.228700     19       nd       nd          0.10          0.00        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.504500      -35.228700     59       nd       nd          0.10          0.00        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.504500      -35.228700     361      nd       nd          7.90          0.40        0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.504500      -35.228700     712      nd       nd          21.60         1.30        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.504500      -35.228700     1620     nd       nd          21.60         1.41        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.499100      -33.573200     112      nd       nd          0.18          0.00        0.13        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.499100      -33.573200     213      nd       nd          7.10          0.36        0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.499100      -33.573200     364      nd       nd          12.40         0.70        0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.499100      -33.573200     717      nd       nd          23.70         1.49        0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.499100      -33.573200     1121     nd       nd          26.40         1.75        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.499100      -33.573200     2237     nd       nd          21.90         1.49        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         24.499100      -33.573200     5992     nd       nd          23.50         1.59        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.501500      -29.890100     21       nd       nd          0.10          0.01        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.501500      -29.890100     61       nd       nd          0.10          0.01        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.501500      -29.890100     362      nd       nd          10.50         0.59        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.501500      -29.890100     2846     nd       nd          21.90         1.45        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         24.501500      -29.890100     4633     nd       nd          23.50         1.58        0.15        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.501300      -28.068600     19       nd       nd          0.10          0.01        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.501300      -28.068600     59       nd       nd          0.10          0.01        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.501300      -28.068600     110      nd       nd          2.50          0.14        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.501300      -28.068600     362      nd       nd          13.80         0.76        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.501300      -28.068600     2794     nd       nd          22.40         1.48        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         24.501300      -28.068600     5698     nd       nd          23.80         1.55        0.22        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.499000      -26.231200     18       nd       nd          0.10          0.02        0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.499000      -26.231200     58       nd       nd          0.10          0.02        0.18        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.499000      -26.231200     109      nd       nd          0.80          0.05        0.12        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.499000      -26.231200     209      nd       nd          4.30          0.21        0.13        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.499000      -26.231200     713      nd       nd          27.70         1.79        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.738200      -22.822300     310      nd       nd          17.30         1.02        0.26        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        24.738200      -22.822300     663      nd       nd          25.00         1.53        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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         24.738200      -22.822300     4974     nd       nd          23.70         1.57        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        25.649900      -20.242500     107      nd       nd          5.50          0.29        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        25.649900      -20.242500     307      nd       nd          10.10         0.52        0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.133600      -18.909800     104      nd       nd          3.90          0.26        0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        26.133600      -18.909800     204      nd       nd          9.60          0.55        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        27.043200      -16.122000     12       nd       nd          0.10          0.02        0.26        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        27.043200      -16.122000     52       nd       nd          0.20          0.05        0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        27.043200      -16.122000     103      nd       nd          4.00          0.25        0.18        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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   26.508100      -71.343300     0        nd       nd          0.04          0.03        0.17        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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   24.502900      -66.192300     0        nd       nd          0.00          0.01        0.14        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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   24.515400      -59.591800     0        nd       nd          0.00          0.01        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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   24.495800      -46.574700     0        nd       nd          0.00          0.01        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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   24.497800      -39.245100     0        nd       nd          0.00          0.00        0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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   24.499500      -31.730800     0        nd       nd          0.00          0.00        0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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   24.513400      -23.494700     0        nd       nd          0.10          0.02        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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   26.814500      -16.784600     0        nd       nd          0.00          0.02        0.17        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.230800      -69.140700     1007.9   7.302    35.1149     19.46         1.28        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.640100      -70.262500     16       21.855   36.3275     0.00          0.00        0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.640100      -70.262500     55.7     21.863   36.3289     0.00          0.00        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.640100      -70.262500     105.2    21.096   36.3733     1.76          0.11        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.738500      -70.558900     12.3     15.475   35.0237     0.00          0.17        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.738500      -70.558900     43.9     14.13    35.1429     0.55          0.24        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.866500      -70.868900     48.6     11.876   34.7372     3.61          0.38        0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        37.322600      -71.679100     44.5     12.743   34.7013     1.79          0.25        0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        37.442900      -71.951300     41.3     16.334   35.3914     0.00          0.06        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        37.611000      -72.201600     3011     2.275    34.8997     15.70         1.11        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.014800      -74.812900     10.9     10.379   33.5686     0.57          0.25        0.11        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.014800      -74.812900     51.1     9.366    33.545      1.47          0.36        0.14        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.014800      -74.812900     101.2    9.064    33.5264     1.86          0.43        0.13        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.014800      -74.812900     115.4    9.092    33.5564     1.92          0.43        0.11        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.014800      -74.812900     11.5     11.863   34.0038     0.00          0.17        0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.994400      -74.795900     51.4     11.922   34.1203     0.18          0.20        0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.994400      -74.795900     150.9    10.312   34.4137     2.70          0.44        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.977100      -74.773800     11.7     10.457   33.6804     0.79          0.29        0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.952100      -74.737400     51.9     10.445   33.7657     1.02          0.32        0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.952100      -74.737400     100.2    8.09     33.5552     1.89          0.46        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.649300      -74.279100     1005     4.202    34.9621     18.54         1.20        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.649300      -74.279100     1506     3.733    34.9431     17.99         1.18        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.649300      -74.279100     2504.3   3.01     34.9346     18.02         1.20        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.649300      -74.279100     12.2     24.799   36.3796     0.14          0.01        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.597000      -74.117000     13.3     24.634   36.3728     0.31          0.00        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.597000      -74.117000     53.4     24.638   36.3723     0.92          0.01        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.361800      -73.769400     152.9    21.955   36.8356     1.48          0.04        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.361800      -73.769400     203.2    20.499   36.7781     1.59          0.06        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.361800      -73.769400     503      16.371   36.2397     11.30         0.58        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.361800      -73.769400     13.1     21.66    36.6121     0.09          0.02        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.361800      -73.769400     42.6     20.901   36.6558     0.17          0.03        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.361800      -73.769400     103      20.552   36.6662     0.46          0.03        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.158700      -73.470200     202.9    19.209   36.6796     2.05          0.09        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.295100      -72.934800     13.7     20.839   36.5626     0.02          0.01        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.418400      -72.407100     304.7    18.697   36.6603     1.81          0.07        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.565600      -71.858700     13       21.476   36.4436     0.11          0.01        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.565600      -71.858700     52.9     21.485   36.4457     0.13          0.00        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.699400      -71.329200     303.3    18.714   36.6511     2.48          0.11        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.699400      -71.329200     13.6     20.887   36.5682     0.05          0.00        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.699400      -71.329200     53.5     20.795   36.5679     0.06          0.00        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.699400      -71.329200     103.6    19.96    36.7103     1.49          0.05        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.832900      -70.799600     203.7    18.963   36.6593     2.43          0.09        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.832900      -70.799600     303.8    18.649   36.6415     2.62          0.10        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.832900      -70.799600     403.8    18.258   36.5839     3.72          0.17        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.967400      -70.247000     53.8     19.26    36.6771     0.33          0.00        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.967400      -70.247000     103.9    19.213   36.6823     0.71          0.01        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.113100      -69.693800     203.8    18.698   36.6397     2.56          0.11        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.113100      -69.693800     304.7    18.32    36.5755     3.86          0.17        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.113100      -69.693800     404.8    18.046   36.5497     4.30          0.20        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.113100      -69.693800     505      17.109   36.3719     7.45          0.39        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.113100      -69.693800     13.3     21.582   36.5238     0.02          0.00        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.113100      -69.693800     45.2     19.501   36.6574     0.07          0.00        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.113100      -69.693800     103.4    19.015   36.6605     1.19          0.03        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.256200      -69.129100     203.6    18.529   36.6527     2.35          0.08        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.246900      -66.085700     13.8     20.885   36.5227     0.04          0.01        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.246900      -66.085700     49.6     20.845   36.5309     0.11          0.01        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.234800      -65.456200     203.2    19.147   36.6451     3.60          0.16        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.234800      -65.456200     302.6    18.741   36.6534     2.58          0.11        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.234800      -65.456200     403.2    18.396   36.6192     3.06          0.14        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.234800      -65.456200     2006.4   3.661    34.9535     18.31         1.19        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.264300      -64.229600     14.2     20.916   36.4779     0.06          0.01        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.264300      -64.229600     47.1     20.599   36.4796     0.32          0.01        0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.264300      -64.229600     104.1    19.597   36.679      2.32          0.09        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.245700      -63.625300     204.2    18.543   36.646      2.48          0.10        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.261600      -62.406400     14.1     19.938   36.6515     0.08          0.01        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.261600      -62.406400     53.8     18.876   36.6275     0.15          0.01        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.261600      -62.406400     84.3     18.595   36.6203     1.51          0.06        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.258600      -61.772500     203.9    18.268   36.6102     2.67          0.11        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.258600      -61.772500     303.9    18.16    36.5954     2.91          0.15        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.258600      -61.772500     403.2    17.99    36.5629     3.48          0.16        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.258600      -61.772500     1994.3   3.713    34.956      18.39         1.19        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.242400      -61.164200     14.1     19.807   36.6652     0.02          0.00        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.242400      -61.164200     54       19.583   36.6597     0.06          0.00        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.242400      -61.164200     103.1    18.634   36.6323     1.77          0.05        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.246800      -60.529500     204      18.305   36.6055     2.57          0.10        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.246800      -60.529500     303.2    18.14    36.5828     3.17          0.12        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.246800      -60.529500     402.9    17.699   36.4844     5.32          0.25        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.097600      -58.712600     13.6     19.306   36.6669     0.02          0.00        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.097600      -58.712600     28.6     19.229   36.667      0.04          0.00        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.097600      -58.712600     103.6    18.898   36.6547     1.75          0.06        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.010500      -58.082800     203.5    18.5     36.6282     2.37          0.10        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.010500      -58.082800     303.5    18.361   36.6227     2.56          0.12        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.010500      -58.082800     403.8    18.239   36.6034     2.98          0.13        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.168200      -57.253900     14.9     19.034   36.6551     0.03          0.00        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.168200      -57.253900     44.9     18.917   36.6556     0.43          0.00        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.168200      -57.253900     105      18.641   36.654      2.26          0.08        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.235000      -56.437600     205.1    18.332   36.6111     2.62          0.10        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.235000      -56.437600     303.6    18.217   36.5965     2.93          0.13        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.244100      -55.608400     13.5     18.891   36.5187     0.08          0.02        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.244100      -55.608400     33.6     18.735   36.5167     0.06          0.02        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.488200      -52.277300     28.5     18.463   36.5099     0.12          0.01        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.488200      -52.277300     103.6    17.709   36.4947     3.03          0.15        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.647200      -51.439200     153.7    17.479   36.4393     3.07          0.15        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.647200      -51.439200     203.4    16.94    36.3529     6.19          0.33        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.243700      -48.966800     39.3     18.817   36.5714     0.02          0.00        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.243700      -48.966800     104.2    18.045   36.5448     3.19          0.14        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.249700      -48.129100     203.8    17.604   36.4701     4.84          0.25        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.249700      -48.129100     303.9    16.661   36.2954     8.27          0.44        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.264500      -47.310200     12.7     18.733   36.5524     0.29          0.00        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.248000      -46.469900     153.3    18.069   36.5832     2.49          0.09        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.248000      -46.469900     203.2    17.967   36.5712     3.10          0.11        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.248000      -46.469900     302.8    17.973   36.5912     2.93          0.11        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.248000      -46.469900     402.9    17.632   36.5074     4.81          0.23        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.248000      -46.469900     552.8    15.539   36.1646     6.46          0.36        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.250800      -45.655200     13.2     18.952   36.5358     0.00          0.01        0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.250800      -45.655200     23.3     18.579   36.5806     0.02          0.02        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.250800      -45.655200     103.2    18.256   36.5766     1.51          0.09        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.253400      -44.824600     203      18.037   36.5754     3.05          0.16        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.247000      -42.543300     12.8     19.71    36.461      0.03          0.01        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.247000      -42.543300     37.7     18.687   36.4638     0.05          0.00        0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.252100      -40.099200     153.5    17.445   36.4195     3.72          0.19        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.249000      -38.863500     13.3     19.38    36.4944     0.03          0.00        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.249000      -38.863500     38.3     18.594   36.4721     0.10          0.00        0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.249000      -38.863500     103.5    17.398   36.4        2.81          0.13        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.243400      -38.269100     203.2    16.821   36.3291     4.62          0.24        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.243400      -38.269100     303.1    15.472   36.0942     7.91          0.45        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.243400      -38.269100     402.9    14.399   35.9363     9.99          0.57        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.243400      -38.269100     552.4    12.475   35.6621     13.33         0.79        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.249200      -36.432000     11.8     19.709   36.4704     0.00          0.03        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.249200      -36.432000     102.4    17.297   36.3674     3.72          0.22        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.249500      -35.815300     152.3    16.904   36.32       3.59          0.21        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.251600      -33.368200     12       19.996   36.6332     0.00          0.00        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.251600      -33.368200     46.9     19.002   36.6074     0.01          0.00        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.251600      -33.368200     101.9    18.596   36.5682     1.08          0.04        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.247300      -32.761600     152.1    17.907   36.4626     2.88          0.13        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.247300      -32.761600     202.1    17.404   36.3929     4.17          0.21        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.247300      -32.761600     302.1    16.313   36.2448     3.63          0.19        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.247300      -32.761600     402.2    14.623   35.9657     9.23          0.53        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.247300      -32.761600     702.2    10.053   35.3717     20.10         1.23        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.247300      -32.761600     1002.4   8.608    35.5507     18.71         1.15        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.247300      -32.761600     1602.5   4.916    35.1198     18.36         1.15        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.247300      -32.761600     2216.5   3.497    34.9671     17.95         1.17        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.247300      -31.531900     12.8     19.298   36.3251     0.02          0.00        0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.247300      -31.531900     52.8     17.794   36.3228     0.09          0.00        0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.246000      -30.934700     102.6    16.788   36.3169     3.39          0.18        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.246000      -30.934700     151.7    16.229   36.2388     5.53          0.30        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.246000      -30.934700     202.8    15.559   36.1278     7.24          0.40        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.246000      -30.934700     302.8    13.981   35.8822     9.51          0.55        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.246000      -30.934700     552.8    11.48    35.5592     15.14         0.91        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.248300      -28.485100     47.9     16.83    36.2111     0.00          0.03        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.248300      -28.485100     102.9    16.429   36.2539     3.09          0.19        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.240600      -27.835200     202.9    15.619   36.1554     5.92          0.36        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.240600      -27.835200     302.5    14.11    35.9033     9.62          0.58        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.240600      -27.835200     403      13.106   35.7573     12.25         0.73        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.252100      -26.651000     14.3     19.224   36.2566     0.02          0.01        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.252100      -26.651000     64.4     16.48    36.1984     0.09          0.02        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.252100      -26.651000     104.4    15.604   36.1663     3.56          0.21        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.250200      -26.033900     304.1    13.305   35.7889     10.55         0.61        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.250200      -26.033900     404.3    12.252   35.6424     13.01         0.77        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.250200      -26.033900     553.9    10.944   35.5067     16.61         0.98        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.250200      -26.033900     2004.5   3.506    34.9667     18.91         1.18        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.247800      -25.419500     12.6     19.176   36.3243     0.00          0.00        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.247800      -25.419500     62.6     17.442   36.2866     0.02          0.01        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.250200      -24.816700     152.6    15.596   36.1879     4.24          0.24        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.250200      -24.816700     2003.7   3.389    34.9353     17.91         1.17        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.249100      -22.980800     15.2     18.494   36.264      0.02          0.00        0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.249100      -22.980800     45.2     17.239   36.2294     0.03          0.00        0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.250000      -22.355000     305.2    13.894   35.8857     8.77          0.51        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.249000      -21.151500     14.1     18.73    36.3239     0.00          0.00        0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.249000      -21.151500     54.1     16.093   36.1424     0.08          0.01        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.249000      -21.151500     104      15.249   36.1213     3.80          0.23        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.249500      -20.527800     204      14.63    36.0653     5.38          0.32        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.251000      -19.913600     14.2     19.236   36.3994     0.00          0.00        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.251000      -19.913600     69.1     16.092   36.1879     0.04          0.01        0.21        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.251000      -19.913600     104.2    15.49    36.2114     3.68          0.23        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.255000      -17.466600     15.9     18.893   36.3674     0.05          0.01        0.07        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.255000      -17.466600     41       18.812   36.364      0.13          0.00        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.255000      -17.466600     105.9    15.728   36.2552     4.54          0.25        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.258600      -16.860000     206.3    14.392   36.023      6.78          0.40        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.258600      -16.860000     306.2    14.027   36.0134     6.91          0.41        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.258600      -16.860000     405.9    13.204   35.8596     8.46          0.50        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.150600      -15.370800     12       19.06    36.559      0.05          0.00        0.08        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.150600      -15.370800     102.1    15.903   36.2552     2.73          0.17        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.993200      -14.958300     152.1    15.294   36.1965     4.92          0.29        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.993200      -14.958300     401.7    12.627   35.7042     12.24         0.73        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.900500      -14.701000     12.6     19.109   36.6044     0.01          0.00        0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.900500      -14.701000     52.3     17.646   36.4481     0.00          0.00        0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.900500      -14.701000     102.8    16.216   36.3412     3.83          0.21        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.792900      -13.990400     152.8    15.505   36.2269     4.93          0.28        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.792900      -13.990400     202.9    15.005   36.1413     5.67          0.32        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.792900      -13.990400     302.8    14.022   36.0032     6.78          0.39        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.792900      -13.990400     3001.9   2.795    34.9472     21.55         1.45        0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.800200      -11.898900     104.3    16.275   36.3952     3.58          0.21        0.06        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.809200      -11.193700     154      15.537   36.268      4.96          0.29        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.809200      -11.193700     203.7    15.036   36.1694     5.73          0.33        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.795700      -10.495000     14.9     20.007   36.5047     0.00          0.00        0.10        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.795700      -10.495000     44.9     16.168   36.1934     0.00          0.02        0.09        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.795700      -10.495000     104.5    14.366   36.0839     6.79          0.39        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.898800      -9.803840      203.7    13.562   35.9467     8.07          0.48        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.898800      -9.803840      303.9    12.717   35.7986     10.76         0.64        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.595300      -8.677370      11.9     19.578   36.4621     0.00          0.01        0.04        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.595300      -8.677370      35       16.209   36.3064     0.00          0.04        0.05        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.639500      -8.661330      101.8    14.921   36.1713     5.96          0.36        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.639500      -8.661330      151.9    14.802   36.1583     6.25          0.38        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.639500      -8.661330      301.8    12.702   35.7278     12.69         0.74        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.639500      -8.661330      701.6    12.441   36.3479     13.37         0.77        0.01        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        36.639500      -8.661330      761      12.799   36.5081     12.28         0.70        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        35.049300      -8.063950      32.7     18.536   36.4191     0.06          0.01        0.03        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        34.582900      -7.820290      801.7    10.483   35.7607     18.59         1.14        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        34.582900      -7.820290      1100.7   9.818    35.9228     18.42         1.13        0.02        North Atlantic   UV oxidation     Mather; R.; Reynolds; S.; Wolff; G. et al. 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        20.030000      -19.270000     1        nd       nd          nd            nd          0.26        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        20.030000      -19.270000     1        nd       nd          nd            nd          0.31        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        20.690000      -24.060000     1        nd       nd          nd            nd          0.25        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        20.690000      -24.060000     1        nd       nd          nd            nd          0.23        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        20.690000      -24.060000     1        nd       nd          nd            nd          0.23        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        21.770000      -26.710000     1        nd       nd          nd            nd          0.23        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        21.770000      -26.710000     1        nd       nd          nd            nd          0.19        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        21.760000      -26.640000     1        nd       nd          nd            nd          0.20        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        21.710000      -26.650000     1        nd       nd          nd            nd          0.21        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        23.000000      -29.390000     1        nd       nd          nd            nd          0.18        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        22.970000      -29.430000     1        nd       nd          nd            nd          0.21        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        22.990000      -29.440000     1        nd       nd          nd            nd          0.17        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        24.600000      -31.240000     1        nd       nd          nd            nd          0.14        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        24.580000      -31.240000     1        nd       nd          nd            nd          0.15        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        24.570000      -31.230000     1        nd       nd          nd            nd          0.15        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        24.490000      -31.250000     1        nd       nd          nd            nd          0.13        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        24.470000      -31.260000     1        nd       nd          nd            nd          0.12        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        30.800000      -169.500000    10       nd       nd          nd            nd          0.10        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        31.500000      -170.400000    10       nd       nd          nd            nd          0.10        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        33.400000      -172.800000    10       nd       nd          nd            nd          0.12        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        33.900000      -173.400000    10       nd       nd          nd            nd          0.13        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        34.600000      -174.300000    10       nd       nd          nd            nd          0.12        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        36.500000      -176.800000    10       nd       nd          nd            nd          0.14        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        36.800000      -177.200000    10       nd       nd          nd            nd          0.12        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        37.500000      -178.200000    10       nd       nd          nd            nd          0.13        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        39.500000      179.100000     10       nd       nd          nd            nd          0.16        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        39.900000      178.400000     10       nd       nd          nd            nd          0.16        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        40.300000      177.800000     10       nd       nd          nd            nd          0.17        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        41.000000      177.000000     10       nd       nd          nd            nd          0.10        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        42.400000      174.900000     10       nd       nd          nd            nd          0.12        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        42.900000      174.100000     10       nd       nd          nd            nd          0.17        North Pacific    Wet oxidation    Yoshimura; T.; Nishioka; J.; Saito; H.; Takeda; S.; Tsuda; A.; & Wells;