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  • Climate - Biogeochemistry Interactions in the Tropical Ocean; SFB754  (3)
  • CTD; CTD/Rosette; CTD 1; CTD 10; CTD 100; CTD 101; CTD 102; CTD 103; CTD 104; CTD 105; CTD 106; CTD 107; CTD 108; CTD 109; CTD 11; CTD 110; CTD 111; CTD 112; CTD 113; CTD 114; CTD 115; CTD 116; CTD 117; CTD 118; CTD 119; CTD 12; CTD 120; CTD 121; CTD 122; CTD 123; CTD 13; CTD 14; CTD 15; CTD 16; CTD 17; CTD 18; CTD 19; CTD 2; CTD 20; CTD 21; CTD 23; CTD 24; CTD 25; CTD 26; CTD 27; CTD 28; CTD 29; CTD 3; CTD 30; CTD 31; CTD 32; CTD 33; CTD 34; CTD 35; CTD 36; CTD 37; CTD 38; CTD 39; CTD 4; CTD 40; CTD 41; CTD 42; CTD 43; CTD 44; CTD 45; CTD 46; CTD 47; CTD 48; CTD 49; CTD 5; CTD 50; CTD 51; CTD 52; CTD 53; CTD 54; CTD 55; CTD 56; CTD 57; CTD 58; CTD 59; CTD 6; CTD 60; CTD 61; CTD 62; CTD 63; CTD 64; CTD 65; CTD 66; CTD 67; CTD 68; CTD 69; CTD 7; CTD 70; CTD 71; CTD 72; CTD 73; CTD 74; CTD 75; CTD 76; CTD 77; CTD 78; CTD 79; CTD 8; CTD 80; CTD 81; CTD 82; CTD 83; CTD 84; CTD 85; CTD 86; CTD 87; CTD 88; CTD 89; CTD 9; CTD 90; CTD 91; CTD 92; CTD 93; CTD 94; CTD 95; CTD 96; CTD 97; CTD 98; CTD 99; CTD-RO; Date/Time of event; DEPTH, water; Elevation of event; Event label; Latitude of event; Longitude of event; M47/1; M47/1_100_CTD14; M47/1_101_CTD15; M47/1_102_CTD16; M47/1_103_CTD17; M47/1_104_CTD18; M47/1_105_CTD19; M47/1_106_CTD20; M47/1_107_CTD21; M47/1_109_CTD23; M47/1_110_CTD24; M47/1_111_CTD25; M47/1_112_CTD26; M47/1_113_CTD27; M47/1_114_CTD28; M47/1_115_CTD29; M47/1_116_CTD30; M47/1_117_CTD31; M47/1_118_CTD32; M47/1_119_CTD33; M47/1_120_CTD34; M47/1_121_CTD35; M47/1_122_CTD36; M47/1_123_CTD37; M47/1_124_CTD38; M47/1_125_CTD39; M47/1_126_CTD40; M47/1_127_CTD41; M47/1_128_CTD42; M47/1_129_CTD43; M47/1_130_CTD44; M47/1_131_CTD45; M47/1_132_CTD46; M47/1_133_CTD47; M47/1_134_CTD48; M47/1_135_CTD49; M47/1_136_CTD50; M47/1_137_CTD51; M47/1_138_CTD52; M47/1_139_CTD53; M47/1_140_CTD54; M47/1_141_CTD55; M47/1_142_CTD56; M47/1_143_CTD57; M47/1_144_CTD58; M47/1_145_CTD59; M47/1_146_CTD60; M47/1_147_CTD61; M47/1_148_CTD62; M47/1_149_CTD63; M47/1_150_CTD64; M47/1_151_CTD65; M47/1_152_CTD66; M47/1_153_CTD67; M47/1_154_CTD68; M47/1_155_CTD69; M47/1_155_CTD70; M47/1_157_CTD71; M47/1_158_CTD72; M47/1_159_CTD73; M47/1_160_CTD74; M47/1_161_CTD75; M47/1_162_CTD76; M47/1_163_CTD77; M47/1_164_CTD78; M47/1_165_CTD79; M47/1_166_CTD80; M47/1_167_CTD81; M47/1_168_CTD82; M47/1_168_CTD83; M47/1_170_CTD84; M47/1_171_CTD85; M47/1_172_CTD86; M47/1_173_CTD87; M47/1_174_CTD88; M47/1_175_CTD89; M47/1_176_CTD90; M47/1_177_CTD91; M47/1_178_CTD92; M47/1_179_CTD93; M47/1_180_CTD94; M47/1_181_CTD95; M47/1_182_CTD96; M47/1_182_CTD97; M47/1_183_CTD98; M47/1_184_CTD99; M47/1_185_CTD100; M47/1_186_CTD101; M47/1_187_CTD102; M47/1_188_CTD103; M47/1_189_CTD104; M47/1_190_CTD105; M47/1_191_CTD106; M47/1_192_CTD107; M47/1_193_CTD108; M47/1_194_CTD109; M47/1_195_CTD110; M47/1_196_CTD111; M47/1_197_CTD112; M47/1_198_CTD113; M47/1_199_CTD114; M47/1_200_CTD115; M47/1_201_CTD116; M47/1_202_CTD117; M47/1_203_CTD118; M47/1_204_CTD119; M47/1_205_CTD120; M47/1_206_CTD121; M47/1_207_CTD122; M47/1_208_CTD123; M47/1_86_CTD1; M47/1_87_CTD2; M47/1_88_CTD3; M47/1_89_CTD4; M47/1_90_CTD5; M47/1_91_CTD6; M47/1_93_CTD7; M47/1_94_CTD8; M47/1_95_CTD9; M47/1_96_CTD10; M47/1_97_CTD11; M47/1_98_CTD12; M47/1_99_CTD13; Meteor (1986); Oxygen; Pressure, water; Salinity; Temperature, water; Temperature, water, potential  (1)
Document type
Keywords
Publisher
Years
  • 1
    facet.materialart.
    Unknown
    Transport, properties and life-cycles of mesoscale eddies in the eastern tropical South Pacific (2018)
    PANGAEA
    In:  Supplement to: Czeschel, Rena; Schütte, Florian; Weller, Robert A; Stramma, Lothar (2018): Transport, properties, and life cycles of mesoscale eddies in the eastern tropical South Pacific. Ocean Science, 14(4), 731-750, https://doi.org/10.5194/os-14-731-2018
    Details
    Publication Date: 2023-10-28
    Description: The influence of mesoscale eddies on the flow field and the water masses, especially the oxygen distribution of the eastern tropical South Pacific is investigated from a mooring, float and satellite data set. Two anticyclonic (ACE1/2), one mode water (MWE) and one cyclonic eddy (CE) are identified and followed in detail with satellite data on their westward transition with velocities of 3.2 to 6.0 cm/s from their generation region, the shelf of the Peruvian and Chilean upwelling regime, across the Stratus Ocean Reference Station (ORS) (~20°S, 85°W) to their decaying region far west in the oligotrophic open ocean. The ORS is located in the transition zone between the oxygen minimum zone and the well-oxygenated South Pacific subtropical gyre. Velocity, hydrographic, and oxygen measurements at the mooring show the impact of eddies on the weak flow region of the eastern tropical South Pacific.
    Keywords: Climate - Biogeochemistry Interactions in the Tropical Ocean; SFB754
    Type: Dataset
    Format: application/zip, 9 datasets
    Location Call Number Limitation Availability
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    DATA PANGAEA
  • 2
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    Unknown
    Nitrogen cycling driven by organic matter export in the South Pacific oxygen minimum zone (2015)
    PANGAEA
    In:  Supplement to: Kalvelage, Tim; Lavik, Gaute; Lam, Phyllis; Contreras, Sergio; Arteaga, Lionel; Löscher, Carolin R; Oschlies, Andreas; Stramma, Lothar; Kuypers, Marcel MM (2013): Nitrogen cycling driven by organic matter export in the South Pacific oxygen minimum zone. Nature Geoscience, 6(3), 228-234, https://doi.org/10.1038/ngeo1739
    Details
    Publication Date: 2023-10-28
    Description: Oxygen minimum zones are expanding globally, and at present account for around 20-40% of oceanic nitrogen loss. Heterotrophic denitrification and anammox-anaerobic ammonium oxidation with nitrite-are responsible for most nitrogen loss in these low-oxygen waters. Anammox is particularly significant in the eastern tropical South Pacific, one of the largest oxygen minimum zones globally. However, the factors that regulate anammox-driven nitrogen loss have remained unclear. Here, we present a comprehensive nitrogen budget for the eastern tropical South Pacific oxygen minimum zone, using measurements of nutrient concentrations, experimentally determined rates of nitrogen transformation and a numerical model of export production. Anammox was the dominant mode of nitrogen loss at the time of sampling. Rates of anammox, and related nitrogen transformations, were greatest in the productive shelf waters, and tailed off with distance from the coast. Within the shelf region, anammox activity peaked in both upper and bottom waters. Overall, rates of nitrogen transformation, including anammox, were strongly correlated with the export of organic matter. We suggest that the sinking of organic matter, and thus the release of ammonium into the water column, together with benthic ammonium release, fuel nitrogen loss from oxygen minimum zones.
    Keywords: Climate - Biogeochemistry Interactions in the Tropical Ocean; SFB754
    Type: Dataset
    Format: application/zip, 6 datasets
    Location Call Number Limitation Availability
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    DATA PANGAEA
  • 3
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    Unknown
    Distribution of neodymium isotopes and concentrations during M77/3 and M77/4 (2013)
    PANGAEA
    In:  Supplement to: Grasse, Patricia; Stichel, Torben; Stumpf, Roland; Stramma, Lothar; Frank, Martin (2012): The distribution of neodymium isotopes and concentrations in the Eastern Equatorial Pacific Water mass advection versus particle exchange. Earth and Planetary Science Letters, 198-207, https://doi.org/10.1016/j.epsl.2012.07.044
    Details
    Publication Date: 2023-10-28
    Description: The radiogenic isotope composition of the Rare Earth Element (REE) neodymium (Nd) is a powerful water mass proxy for present and past ocean circulation. The processes controlling the Nd budget of the global ocean are not quantitatively understood and in particular source and sink mechanisms are still under debate. In this study we present the first full water column data set of dissolved Nd isotope compositions and Nd concentrations for the Eastern Equatorial Pacific (EEP), where one of the globally largest Oxygen Minimum Zones (OMZ) is located. This region is of particular interest for understanding the biogeochemical cycling of REEs because anoxic conditions may lead to release of REEs from the shelf, whereas high particle densities and fluxes potentially remove the REEs from the water column. Data were obtained between 11400N and 161S along a nearshore and an offshore transect. Near surface zonal current bands, such as the Equatorial Undercurrent (EUC) and the Subsurface Countercurrent (SSCC), which are supplying oxygen-rich water to the OMZ are characterized by radiogenic Nd isotope signatures (eNd=-2). Surface waters in the northernmost part of the study area are even more radiogenic (eNd = +3), most likely due to release of Nd from volcanogenic material. Deep and bottom waters at the southernmost offshore station (141S) are clearly controlled by advection of water masses with less radiogenic signatures (eNd=- 7) originating from the Southern Ocean. Towards the equator, however, the deep waters show a clear trend towards more radiogenic values of up to eNd=-2. The northernmost station located in the Panama basin shows highly radiogenic Nd isotope signatures in the entire water column, which indicates that particle scavenging, downward transport and release processes play an important role. This is supported by relatively low Nd concentrations in deep waters (3000-6000 m) in the EEP (20 pmol/kg) compared to locations in the Northern and Central Pacific (40-60 pmol/kg), which suggests enhanced removal of Nd in the EEP.
    Keywords: Climate - Biogeochemistry Interactions in the Tropical Ocean; SFB754
    Type: Dataset
    Format: application/zip, 2 datasets
    Location Call Number Limitation Availability
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    DATA PANGAEA
  • 4
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    Unknown
    Physical oceanography during METEOR cruise M47/1 (2012)
    PANGAEA
    In:  IFM-GEOMAR Leibniz-Institute of Marine Sciences, Kiel University
    Details
    Publication Date: 2023-08-12
    Keywords: CTD; CTD/Rosette; CTD 1; CTD 10; CTD 100; CTD 101; CTD 102; CTD 103; CTD 104; CTD 105; CTD 106; CTD 107; CTD 108; CTD 109; CTD 11; CTD 110; CTD 111; CTD 112; CTD 113; CTD 114; CTD 115; CTD 116; CTD 117; CTD 118; CTD 119; CTD 12; CTD 120; CTD 121; CTD 122; CTD 123; CTD 13; CTD 14; CTD 15; CTD 16; CTD 17; CTD 18; CTD 19; CTD 2; CTD 20; CTD 21; CTD 23; CTD 24; CTD 25; CTD 26; CTD 27; CTD 28; CTD 29; CTD 3; CTD 30; CTD 31; CTD 32; CTD 33; CTD 34; CTD 35; CTD 36; CTD 37; CTD 38; CTD 39; CTD 4; CTD 40; CTD 41; CTD 42; CTD 43; CTD 44; CTD 45; CTD 46; CTD 47; CTD 48; CTD 49; CTD 5; CTD 50; CTD 51; CTD 52; CTD 53; CTD 54; CTD 55; CTD 56; CTD 57; CTD 58; CTD 59; CTD 6; CTD 60; CTD 61; CTD 62; CTD 63; CTD 64; CTD 65; CTD 66; CTD 67; CTD 68; CTD 69; CTD 7; CTD 70; CTD 71; CTD 72; CTD 73; CTD 74; CTD 75; CTD 76; CTD 77; CTD 78; CTD 79; CTD 8; CTD 80; CTD 81; CTD 82; CTD 83; CTD 84; CTD 85; CTD 86; CTD 87; CTD 88; CTD 89; CTD 9; CTD 90; CTD 91; CTD 92; CTD 93; CTD 94; CTD 95; CTD 96; CTD 97; CTD 98; CTD 99; CTD-RO; Date/Time of event; DEPTH, water; Elevation of event; Event label; Latitude of event; Longitude of event; M47/1; M47/1_100_CTD14; M47/1_101_CTD15; M47/1_102_CTD16; M47/1_103_CTD17; M47/1_104_CTD18; M47/1_105_CTD19; M47/1_106_CTD20; M47/1_107_CTD21; M47/1_109_CTD23; M47/1_110_CTD24; M47/1_111_CTD25; M47/1_112_CTD26; M47/1_113_CTD27; M47/1_114_CTD28; M47/1_115_CTD29; M47/1_116_CTD30; M47/1_117_CTD31; M47/1_118_CTD32; M47/1_119_CTD33; M47/1_120_CTD34; M47/1_121_CTD35; M47/1_122_CTD36; M47/1_123_CTD37; M47/1_124_CTD38; M47/1_125_CTD39; M47/1_126_CTD40; M47/1_127_CTD41; M47/1_128_CTD42; M47/1_129_CTD43; M47/1_130_CTD44; M47/1_131_CTD45; M47/1_132_CTD46; M47/1_133_CTD47; M47/1_134_CTD48; M47/1_135_CTD49; M47/1_136_CTD50; M47/1_137_CTD51; M47/1_138_CTD52; M47/1_139_CTD53; M47/1_140_CTD54; M47/1_141_CTD55; M47/1_142_CTD56; M47/1_143_CTD57; M47/1_144_CTD58; M47/1_145_CTD59; M47/1_146_CTD60; M47/1_147_CTD61; M47/1_148_CTD62; M47/1_149_CTD63; M47/1_150_CTD64; M47/1_151_CTD65; M47/1_152_CTD66; M47/1_153_CTD67; M47/1_154_CTD68; M47/1_155_CTD69; M47/1_155_CTD70; M47/1_157_CTD71; M47/1_158_CTD72; M47/1_159_CTD73; M47/1_160_CTD74; M47/1_161_CTD75; M47/1_162_CTD76; M47/1_163_CTD77; M47/1_164_CTD78; M47/1_165_CTD79; M47/1_166_CTD80; M47/1_167_CTD81; M47/1_168_CTD82; M47/1_168_CTD83; M47/1_170_CTD84; M47/1_171_CTD85; M47/1_172_CTD86; M47/1_173_CTD87; M47/1_174_CTD88; M47/1_175_CTD89; M47/1_176_CTD90; M47/1_177_CTD91; M47/1_178_CTD92; M47/1_179_CTD93; M47/1_180_CTD94; M47/1_181_CTD95; M47/1_182_CTD96; M47/1_182_CTD97; M47/1_183_CTD98; M47/1_184_CTD99; M47/1_185_CTD100; M47/1_186_CTD101; M47/1_187_CTD102; M47/1_188_CTD103; M47/1_189_CTD104; M47/1_190_CTD105; M47/1_191_CTD106; M47/1_192_CTD107; M47/1_193_CTD108; M47/1_194_CTD109; M47/1_195_CTD110; M47/1_196_CTD111; M47/1_197_CTD112; M47/1_198_CTD113; M47/1_199_CTD114; M47/1_200_CTD115; M47/1_201_CTD116; M47/1_202_CTD117; M47/1_203_CTD118; M47/1_204_CTD119; M47/1_205_CTD120; M47/1_206_CTD121; M47/1_207_CTD122; M47/1_208_CTD123; M47/1_86_CTD1; M47/1_87_CTD2; M47/1_88_CTD3; M47/1_89_CTD4; M47/1_90_CTD5; M47/1_91_CTD6; M47/1_93_CTD7; M47/1_94_CTD8; M47/1_95_CTD9; M47/1_96_CTD10; M47/1_97_CTD11; M47/1_98_CTD12; M47/1_99_CTD13; Meteor (1986); Oxygen; Pressure, water; Salinity; Temperature, water; Temperature, water, potential
    Type: Dataset
    Format: text/tab-separated-values, 2358737 data points
    Location Call Number Limitation Availability
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    DATA PANGAEA
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