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  • 1995-1999  (1,636,858)
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  • 1
    facet.materialart.
    Unknown
    Chemistry of pore water from Arctic sediments (1996)
    PANGAEA
    In:  Supplement to: Hulth, Stefan; Hall, Per; Blackburn, T H; Landén, A (1996): Arctic sediments (Svalbard): pore water and solid phase distributions of C, N, P and Si. Polar Biology, 16(6), 447-462, https://doi.org/10.1007/BF02390426
    Details
    Publication Date: 2024-07-01
    Description: Pore water and solid phase distributions of C, N, P and Si in sediments of the Arctic Ocean (Svalbard area) have been investigated. Concentrations of organic carbon (Corg) in the solid phase of the sediment varied from 1.3 to 2.8% (mean 1.9%), with highest concentrations found at shallow stations south/southwest of Svalbard. Relatively low concentrations were obtained at the deeper stations north/northeast of Svalbard. Atomic carbon to nitrogen ratios in the surface sediment ranged from below 8 to above 10. For some stations, high C/N ratios together with high concentrations of Corg suggest that sedimentary organic matter is mainly of terrigenous origin and not from overall biological activity in the water column. Organic matter reactivity (defined as the total sediment oxygen consumption rate normalized to the organic carbon content of the surface sediment) correlated with water depth at all investigated stations. However, the stations could be divided into two separate groups with different reactivity characteristics, representing the two most dominant hydrographic regimes: the region west of Svalbard mainly influenced by the West Spitsbergen Current, and the area east of Svalbard where Arctic polar water set the environmental conditions. Decreasing sediment reactivity with water depth was confirmed by the partitioning between organic and inorganic carbon of the surface sediment. The ratio between organic and inorganic carbon at the sediment-water interface decreased exponentially with water depth: from indefinite values at shallow stations in the central Barents Sea, to approximately 1 at deep stations north of Svalbard. At stations east of Svalbard there was an inverse linear correlation between the organic matter reactivity (as defined above) and concentration of dissolved organic carbon (DOC) in the pore water. The more reactive the sediment, the less DOC existed in the pore water and the more total carbonate (Ct or Sum CO2) was present. This observation suggests that DOC produced in reactive sediments is easily metabolizable to CO2. Sediment accumulation rates of opaline silica ranged from 0.35 to 5.7 µmol SiO2 m**-2 d**-1 (mean 1.3 µmol SiO2 m**-2d**-1), i.e. almost 300 times lower than rates previously reported for the Ross Sea, Antarctica. Concentrations of ammonium and nitrate in the pore water at the sediment-water interface were related to organic matter input and water depth. In shallow regions with highly reactive organic matter, a pool of ammonium was present in the pore water, while nitrate conoentrations were low. In areas where less reactive organic matter was deposited at the sediment surface, the deeper zone of nitrification caused a build-up of nitrate in the pore water while ammonium was almost depleted. Nitrate penetrated from 1.8 to 〉= 5.8 cm into the investigated sediments. Significantly higher concentrations of 'total' dissolved nitrogen (defined as the sum of NO3, NO2, NH4 and urea) in sediment pore water were found west compared to east of Svalbard. The differences in organic matter reactivity, as well as in pore water distribution patterns of 'total' dissolved nitrogen between the two areas, probably reflect hydrographic factors (such as ice coverage and production/import of particulate organic material) related to the dominant water mass (Atlantic or Arctic Polar) in each of the two areas.
    Keywords: ARK-VIII/2; AWI; AWI_Paleo; Barents Sea; Giant box corer; GKG; MUC; MULT; MultiCorer; Multiple investigations; ORFOIS; Origin and Fate of Biogenic Particle Fluxes in the Ocean; Paleoenvironmental Reconstructions from Marine Sediments @ AWI; Polarstern; PS19/040; PS19/045; PS19/050; PS19/055; PS19/078; PS19/082; PS19/084; PS19/086; PS19/098; PS19/100; PS19/101; PS19/105; PS19/108; PS19/112; PS19/119; PS19/134; PS19/143; PS19/146; PS19 EPOS II; PS2111-2; PS2113-2; PS2114-2; PS2115-1; PS2117-1; PS2121-3; PS2122-1; PS2123-4; PS2128-1; PS2129-3; PS2130-2; PS2133-1; PS2134-1; PS2138-5; PS2144-3; PS2150-1; PS2153-1; PS2154-1; Silicon Cycling in the World Ocean; SINOPS; Svalbard; Yermak Plateau
    Type: Dataset
    Format: application/zip, 2 datasets
    Location Call Number Expected Availability
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  • 2
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    Unknown
    Clay mineralogy of South Atlantic surface sediments (1996)
    PANGAEA
    In:  Supplement to: Petschick, Rainer; Kuhn, Gerhard; Gingele, Franz (1996): Clay mineral distribution in surface sediments of the South Atlantic: sources, transport, and relation to oceanography. Marine Geology, 130(3-4), 203-229, https://doi.org/10.1016/0025-3227(95)00148-4
    Details
    Publication Date: 2024-07-01
    Description: Surface samples, mostly from abyssal sediments of the South Atlantic, from parts of the equatorial Atlantic, and of the Antarctic Ocean, were investigated for clay content and clay mineral composition. Maps of relative clay mineral content were compiled, which improve previous maps by showing more details, especially at high latitudes. Large-scale relations regarding the origin and transport paths of detrital clay are revealed. High smectite concentrations are observed in abyssal regions, primarily derived from southernmost South America and from minor sources in Southwest Africa. Near submarine volcanoes of the Antarctic Ocean (South Sandwich, Bouvet Island) smectite contents exhibit distinct maxima, which is ascribed to the weathering of altered basalts and volcanic glasses. The illite distribution can be subdivided into five major zones including two maxima revealing both South African and Antarctic sources. A particularly high amount of Mg- and Fe-rich illites are observed close to East Antarctica. They are derived from biotite-bearing crystalline rocks and transported to the west by the East Antarctic Coastal Current. Chiorite and well-crystallized dioctaedral illite are typical minerals enriched within the Subantarctic and Polarfrontal-Zone but of minor importance off East Antarctica. Kaolinite dominates the clay mineral assemblage at low latitudes, where the continental source rocks (West Africa, Brazil) are mainly affected by intensive chemical weathering. Surprisingly, a slight increase of kaolinite is observed in the Enderby Basin and near the Filchner-Ronne Ice shelf. The investigated area can be subdivided into ten, large-scale clay facies zones with characteristic possible source regions and transport paths. Clay mineral assemblages of the largest part of the South Atlantic, especially of the western basins are dominated by chlorite and illite derived from the Antarctic Peninsula and southernmost South America and supported by advection within the Circumantarctic Deep Water flow. In contrast, the East Antarctic provinces are relatively small. Assemblages of the eastern basins north of 30°S are strongly influenced by African sources, controlled by weathering regimes on land and by a complex interaction of wind, river and deep ocean transport. The strong gradient in clay mineral composition at the Brazilian slope indicate a relatively low contribution of tropically derived assemblages to the western basins.
    Keywords: 06MT15_2; Adelaide Island; Agulhas Basin; Agulhas Ridge; Amazon Fan; Angola Basin; Antarctic Peninsula; ANTARTIDA8611; ANT-I/2; ANT-II/3; ANT-II/4; ANT-III/3; ANT-IV/2; ANT-IV/3; ANT-IV/4; ANT-IX/2; ANT-IX/3; ANT-IX/4; ANT-V/4; ANT-VI/2; ANT-VI/3; ANT-VIII/3; ANT-VIII/5; ANT-VIII/6; ANT-X/2; ANT-X/4; ANT-X/5; ANT-X/6; ANT-XI/2; ANT-XI/4; ANT-XII/4; Anvers Island; Argentine Basin; Argentine Islands; Astrid Ridge; Atka Bay; Atlantic Indik Ridge; Atlantic Ridge; AWI_Paleo; Barents Sea; BC; Box corer; Bransfield Strait; Brazil Basin; Camp Norway; Cape Basin; Cape Blanc; Cape Fiske; Congo Fan; Conrad Rise; Cosmonauts Sea; CTD/Rosette; CTD-RO; D-DCP-1; D-EL-1; DGS-13; DGS-14; DGS-15; DGS-16; DGS-18; Discovery Seamount; D-ORC-013; D-ORC-015; D-ORC-017; D-ORC-023; D-ORC-024; D-ORC-025; D-PA-1; Drake Passage; Dredge; DRG; D-ST-1B; D-ST-2; D-ST-3; D-ST-4; East Brazil Basin; Eastern Rio Grande Rise; Eastern Weddell Sea, Southern Ocean; EL-443; EL-444; EL-445; EL-446; EL-447; EL-448; EL-449; Equatorial Atlantic; Falkland Islands; Filchner Shelf; Filchner Trough; Fram Strait; GeoB1000-1; GeoB1000-2; GeoB1001-1; GeoB1001-2; GeoB1004-2; GeoB1004-3; GeoB1005-2; GeoB1005-3; GeoB1006-2; GeoB1006-3; GeoB1007-2; GeoB1007-3; GeoB1008-6; GeoB1010-3; GeoB1011-2; GeoB1012-1; GeoB1012-2; GeoB1013-2; GeoB1013-3; GeoB1014-2; GeoB1015-2; GeoB1016-2; GeoB1019-2; GeoB1019-3; GeoB1020-1; GeoB1021-3; GeoB1022-2; GeoB1022-3; GeoB1023-2; GeoB1024-3; GeoB1025-2; GeoB1026-3; GeoB1027-2; GeoB1028-4; GeoB1029-1; GeoB1031-1; GeoB1032-2; GeoB1033-3; GeoB1034-1; GeoB1035-3; GeoB1036-3; GeoB1037-1; GeoB1037-2; GeoB1039-1; GeoB1040-3; GeoB1041-1; GeoB1043-2; GeoB1044-3; GeoB1046-2; GeoB1048-2; GeoB1101-4; GeoB1102-3; GeoB1103-3; GeoB1104-5; GeoB1105-3; GeoB1106-5; GeoB1108-6; GeoB1109-4; GeoB1110-3; GeoB1111-5; GeoB1112-3; GeoB1113-7; GeoB1114-3; GeoB1115-4; GeoB1116-1; GeoB1117-3; GeoB1118-2; GeoB1119-2; GeoB1120-3; GeoB1121-1; GeoB1122-2; GeoB1203-2; GeoB1204-3; GeoB1205-2; GeoB1206-1; GeoB1207-2; GeoB1208-1; GeoB1209-1; GeoB1210-3; GeoB1211-1; GeoB1212-2; GeoB1213-2; GeoB1215-1; GeoB1216-2; GeoB1217-1; GeoB1218-1; GeoB1220-2; GeoB1306-1; GeoB1307-2; GeoB1308-1; GeoB1309-3; GeoB1310-1; GeoB1313-1; GeoB1314-1; GeoB1401-1; GeoB1403-2; GeoB1405-7; GeoB1407-7; GeoB1413-2; GeoB1414-2; GeoB1415-1; GeoB1417-2; GeoB1418-1; GeoB1419-1; GeoB1420-1; GeoB1421-1; GeoB1501-3; GeoB1503-2; GeoB1504-1; GeoB1505-3; GeoB1506-1; GeoB1508-1; GeoB1509-2; GeoB1510-1; GeoB1511-6; GeoB1512-2; GeoB1513-2; GeoB1514-4; GeoB1515-2; GeoB1516-1; GeoB1517-1; GeoB1518-1; GeoB1519-2; GeoB1520-1; GeoB1521-2; GeoB1522-1; GeoB1523-2; GeoB1601-6; GeoB1613-1; GeoB1701-1; GeoB1702-6; GeoB1703-5; GeoB1704-1; GeoB1705-2; GeoB1706-1; GeoB1707-2; GeoB1709-3; GeoB1710-2; GeoB1711-5; GeoB1712-2; GeoB1713-6; GeoB1714-1; GeoB1715-1; GeoB1716-2; GeoB1717-2; GeoB1718-1; GeoB1719-5; GeoB1720-4; GeoB1721-4; GeoB1722-3; GeoB1724-3; GeoB1725-1; GeoB1726-1; GeoB1726-2; GeoB1728-3; GeoB1729-1; GeoB1901-1; GeoB1902-3; GeoB1903-1; GeoB1904-1; GeoB1905-1; GeoB1906-1; GeoB1907-1; GeoB1908-1; GeoB2002-2; GeoB2004-1; GeoB2007-1; GeoB2008-1; GeoB2009-1; GeoB2010-1; GeoB2011-1; GeoB2016-3; GeoB2018-1; GeoB2019-2; GeoB2021-4; GeoB2022-3; GeoB2101-1; GeoB2102-1; GeoB2104-1; GeoB2105-3; GeoB2106-1; GeoB2107-5; GeoB2108-1; GeoB2109-3; GeoB2110-1; GeoB2111-2; GeoB2112-1; GeoB2113-1; GeoB2116-2; GeoB2117-4; GeoB2118-1; GeoB2119-2; GeoB2120-1; GeoB2121-1; GeoB2122-1; GeoB2123-1; GeoB2124-1; GeoB2125-2; GeoB2126-1; GeoB2127-1; GeoB2128-1; GeoB2130-1; GeoB2201-1; GeoB2202-5; GeoB2204-1; GeoB2205-4; GeoB2206-1; GeoB2207-2; GeoB2208-1; GeoB2212-1; GeoB2213-1; GeoB2214-2; GeoB2215-8; GeoB2216-2; GeoB2701-2; GeoB2703-6; GeoB2704-1; GeoB2705-7; GeoB2706-6; GeoB2708-5; GeoB2712-1; GeoB2714-5; GeoB2715-1; GeoB2717-8; GeoB2718-1; GeoB2719-1; GeoB2721-2; GeoB2722-1; GeoB2722-2; GeoB2723-1; GeoB2724-6; GeoB2725-1; GeoB2726-3; GeoB2727-1; GeoB2729-1; GeoB2730-1; GeoB2731-1; GeoB2801-1; GeoB2802-1; GeoB2803-1; GeoB2804-2; GeoB2805-1; GeoB2806-6; GeoB2808-3; GeoB2809-2; GeoB2810-2; GeoB2811-1; GeoB2813-1; GeoB2814-3; GeoB2817-3; GeoB2822-3; GeoB2824-1; GeoB2825-3; GeoB2826-1; GeoB2828-1; GeoB2829-3; GeoB2903-1; GeoB2904-11; GeoB2905-1; GeoB2906-3; GeoB2907-1; GeoB2908-8; GeoB2909-1; GeoB2911-2; GeoB2912-1; Giant box corer; GIK17836-1; GIK17843-1; GIK17851-1; GIK17862-1; GIK17866-1; GIK17884-1; GIK17912-1; GKG; Gould Bay; Gravity corer (Kiel type); Greenland Slope; GS-051; GS-053; GS-060; GS-061; GS-073; GS-074; GS-076; GS-083; GS-103; GS-105; GS-136; GS-139; GS-140; GS-142; GS-152; Guinea Basin; Halley Bay; Hope Bay; Hunter Channel; Indian-Antarctic Ridge; Islas Orcadas; Kapp Norvegia; King George Island, Antarctic Peninsula; KL; Kongo delta; Lazarev Sea; Lyddan Island; M12/1; M15/2; M16/1; M16/2; M20/1; M20/2; M23/1; M23/2; M23/3; M29/1; M29/2; M29/3; M6/6; M9/4; Maud Rise; Meteor (1986); Meteor Rise; MG; MIC; Mid Atlantic Ridge; MiniCorer; Mooring (long time); MOORY; MSN; MUC; Multiboxcorer; MultiCorer; Multiple opening/closing net; Namibia Continental Margin; Namibia continental slope; Northern Brasil-Basin; Northern Guinea Basin; Nuevo Alcocero; off Cape Blanc; off Gran Canaria; off Kunene; ORC-301; ORC-312; ORC-313; ORC-329; Paleoenvironmental Reconstructions from Marine Sediments @ AWI; Piston corer (BGR type); PLA; Plankton net; Polarstern; Polarstern Kuppe; PS01; PS01/154; PS01/155; PS01/156; PS01/161; PS01/162; PS01/168; PS01/177; PS01/184; PS01/186; PS01/189; PS04; PS04/225; PS04/254; PS04/257; PS04/260; PS04/262; PS04/266; PS04/271; PS04/273; PS04/318; PS04/334; PS04/335; PS04/340; PS04/346; PS04/351; PS04/357; PS04/367; PS04/370; PS04/380; PS04/382; PS04/389; PS04/414; PS04/423; PS04/429; PS04/433; PS04/440; PS04/447; PS04/449; PS04/472; PS04/477; PS04/481; PS04/484; PS04/495; PS04/500; PS04/508; PS04/509; PS04/540; PS06/288; PS06/289; PS06/301; PS06/302; PS06/303; PS06/304; PS06/306; PS06/311; PS06/313; PS06 SIBEX; PS08; PS08/284; PS08/289; PS08/321; PS08/324; PS08/327; PS08/333; PS08/335; PS08/336; PS08/338; PS08/340; PS08/344; PS08/345; PS08/346; PS08/347; PS08/350; PS08/353; PS08/354; PS08/355; PS08/356; PS08/357; PS08/358; PS08/359; PS08/360; PS08/361; PS08/364; PS08/365; PS08/366; PS08/367; PS08/368; PS08/369; PS08/374; PS08/375; PS08/379; PS08/380; PS08/381; PS08/382; PS08/384; PS08/385; PS08/386; PS08/387; PS08/394; PS08/396; PS08/401; PS08/402; PS08/410; PS08/428; PS08/430; PS08/432; PS08/438; PS08/439; PS08/440; PS08/442; PS08/445; PS08/449; PS08/450; PS08/452; PS08/480; PS08/481; PS08/482; PS08/483; PS08/504; PS08/507; PS08/509; PS08/529; PS08/533; PS08/564; PS08/585; PS08/601; PS08/607; PS08/610; PS08/621; PS08/627; PS10; PS10/668; PS10/672; PS10/673; PS10/675; PS10/678; PS10/682; PS10/684; PS10/686; PS10/688; PS10/690; PS10/694; PS10/697; PS10/699; PS10/701; PS10/703; PS10/707; PS10/711; PS10/719; PS10/725; PS10/738; PS10/740; PS10/748; PS10/757; PS10/760; PS10/762; PS10/766; PS10/768; PS10/778; PS10/782; PS10/784; PS10/794; PS10/804; PS10/809; PS10/813; PS10/816; PS10/818; PS10/820; PS10/824; PS1010-1; PS1011-1; PS1012-1; PS1013-1; PS1014-1; PS1015-1; PS1016-1; PS1017-1; PS1018-1; PS1019-1; PS1138-8; PS1167-5; PS1170-4; PS1173-6; PS1175-1; PS1179-1; PS1184-6; PS1186-3; PS1194-1; PS1196-1; PS1197-1; PS1198-1; PS1199-1; PS12; PS12/116; PS12/117; PS12/119; PS12/122; PS12/127; PS12/128; PS12/129; PS12/130; PS12/132; PS12/133; PS12/185; PS12/186; PS12/193; PS12/194; PS12/195; PS12/196; PS12/199; PS12/200; PS12/238; PS12/242; PS12/244; PS12/247; PS12/248; PS12/250; PS12/252; PS12/260; PS12/266; PS12/271; PS12/273+276; PS12/280; PS12/284; PS12/287; PS12/289; PS12/291; PS12/298; PS12/300; PS12/302; PS12/305; PS12/308; PS12/310; PS12/312; PS12/314; PS12/316; PS12/319; PS12/321; PS12/323; PS12/325; PS12/327; PS12/333; PS12/336; PS12/338; PS12/340; PS12/342; PS12/344; PS12/346; PS12/348; PS12/350; PS12/352; PS12/354; PS12/356; PS12/358; PS12/360; PS12/364; PS12/366; PS12/368; PS12/372; PS12/374; PS12/376; PS12/378; PS12/380; PS12/382; PS12/384; PS12/387;
    Type: Dataset
    Format: application/zip, 2 datasets
    Location Call Number Expected Availability
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  • 3
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    Unknown
    Sedimentology of surface samples from the Weddell Sea, Antarctica (1999)
    PANGAEA
    In:  Supplement to: Diekmann, Bernhard; Kuhn, Gerhard (1999): Provenance and dispersal of glacial-marine surface sediments in the Weddell Sea and adjoining areas, Antarctica: ice-rafting versus current transport. Marine Geology, 158(1-4), 209-231, https://doi.org/10.1016/S0025-3227(98)00165-0
    Details
    Publication Date: 2024-07-01
    Description: Mineralogical and granulometric properties of glacial-marine surface sediments of the Weddell Sea and adjoining areas were studied in order to decipher spatial variations of provenance and transport paths of terrigenous detritus from Antarctic sources. The silt fraction shows marked spatial differences in quartz contents. In the sand fractions heavy-mineral assemblages display low mineralogical maturity and are dominated by garnet, green hornblende, and various types of clinopyroxene. Cluster analysis yields distinct heavy-mineral assemblages, which can be attributed to specific source rocks of the Antarctic hinterland. The configuration of modern mineralogical provinces in the near-shore regions reflects the geological variety of the adjacent hinterland. In the distal parts of the study area, sand-sized heavy minerals are good tracers of ice-rafting. Granulometric characteristics and the distribution of heavy-mineral provinces reflect maxima of relative and absolute accumulation of ice-rafted detritus in accordance with major iceberg drift tracks in the course of the Weddell Gyre. Fine-grained and coarse-grained sediment fractions may have different origins. In the central Weddell Sea, coarse ice-rafted detritus basically derives from East Antarctic sources, while the fine-fraction is discharged from weak permanent bottom currents and/or episodic turbidity currents and shows affinities to southern Weddell Sea sources. Winnowing of quartz-rich sediments through intense bottom water formation in the southern Weddell Sea provides muddy suspensions enriched in quartz. The influence of quartz-rich suspensions moving within the Weddell Gyre contour current can be traced as far as the continental slope in the northwestern Weddell Sea. In general, the focusing of mud by currents significantly exceeds the relative and absolute contribution of ice-rafted detritus beyond the shelves of the study area.
    Keywords: Adelaide Island; Antarctic Peninsula; ANTARTIDA8611; ANT-I/2; ANT-II/3; ANT-II/4; ANT-III/3; ANT-IV/2; ANT-IV/3; ANT-IV/4; ANT-IX/2; ANT-IX/3; ANT-V/4; ANT-VI/2; ANT-VI/3; ANT-VIII/5; ANT-VIII/6; ANT-X/2; ANT-X/4; ANT-X/5; ANT-X/6; ANT-XI/2; ANT-XI/4; ANT-XIV/3; Anvers Island; Argentine Islands; Astrid Ridge; Atka Bay; AWI_Paleo; Barents Sea; BC; Box corer; Bransfield Strait; Camp Norway; Cape Fiske; Cosmonauts Sea; CTD/Rosette; CTD-RO; D-EL-1; D-ORC-011; D-ORC-013; D-ORC-015; D-ORC-017; D-ORC-023; D-ORC-024; D-ORC-025; D-ORC-142; D-PA-1; Drake Passage; Dredge; DRG; D-ST-2; D-ST-3; D-ST-4; Eastern Weddell Sea, Southern Ocean; EL-443; EL-444; EL-445; EL-446; EL-447; EL-448; EL-449; Filchner Shelf; Filchner Trough; Fram Strait; Giant box corer; GKG; Gould Bay; Gravity corer (Kiel type); Greenland Slope; GS-053; GS-076; GS-152; Halley Bay; Hope Bay; Islas Orcadas; Kapp Norvegia; King George Island, Antarctic Peninsula; KL; Lazarev Sea; Lyddan Island; Maud Rise; MG; MIC; MiniCorer; MUC; Multiboxcorer; MultiCorer; Nuevo Alcocero; ORC-301; ORC-312; ORC-313; ORC-329; Paleoenvironmental Reconstructions from Marine Sediments @ AWI; Piston corer (BGR type); Polarstern; Polarstern Kuppe; PS01; PS01/154; PS01/155; PS01/156; PS01/161; PS01/162; PS01/177; PS01/184; PS01/186; PS01/189; PS04; PS04/225; PS04/254; PS04/256; PS04/257; PS04/258; PS04/260; PS04/261; PS04/262; PS04/263; PS04/264; PS04/265; PS04/266; PS04/271; PS04/273; PS04/318; PS04/334; PS04/335; PS04/340; PS04/346; PS04/351; PS04/357; PS04/367; PS04/370; PS04/380; PS04/382; PS04/389; PS04/414; PS04/423; PS04/429; PS04/433; PS04/440; PS04/447; PS04/449; PS04/472; PS04/477; PS04/481; PS04/484; PS04/495; PS04/500; PS04/508; PS04/509; PS06/288; PS06/289; PS06/301; PS06/302; PS06/303; PS06/304; PS06/306; PS06/311; PS06/313; PS06 SIBEX; PS08; PS08/284; PS08/289; PS08/321; PS08/324; PS08/327; PS08/333; PS08/335; PS08/336; PS08/338; PS08/340; PS08/344; PS08/345; PS08/346; PS08/347; PS08/350; PS08/353; PS08/354; PS08/355; PS08/356; PS08/357; PS08/358; PS08/359; PS08/360; PS08/361; PS08/364; PS08/365; PS08/366; PS08/367; PS08/368; PS08/369; PS08/374; PS08/375; PS08/379; PS08/380; PS08/381; PS08/382; PS08/384; PS08/385; PS08/386; PS08/387; PS08/394; PS08/396; PS08/397; PS08/401; PS08/402; PS08/410; PS08/428; PS08/430; PS08/432; PS08/438; PS08/439; PS08/440; PS08/442; PS08/445; PS08/449; PS08/450; PS08/452; PS08/480; PS08/481; PS08/482; PS08/483; PS08/564; PS08/585; PS08/601; PS08/607; PS08/610; PS08/621; PS08/627; PS10; PS10/668; PS10/672; PS10/673; PS10/675; PS10/678; PS10/682; PS10/684; PS10/686; PS10/688; PS10/690; PS10/694; PS10/697; PS10/699; PS10/701; PS10/703; PS10/707; PS10/711; PS10/719; PS10/725; PS10/738; PS10/740; PS10/748; PS10/757; PS10/760; PS10/762; PS10/766; PS10/768; PS10/778; PS10/782; PS10/784; PS10/794; PS10/804; PS10/813; PS10/816; PS10/818; PS10/820; PS10/824; PS1010-1; PS1011-1; PS1012-1; PS1013-1; PS1014-1; PS1016-1; PS1017-1; PS1018-1; PS1019-1; PS1138-8; PS1167-5; PS1169-1; PS1170-4; PS1171-1; PS1173-6; PS1174-2; PS1175-1; PS1176-3; PS1177-1; PS1178-4; PS1179-1; PS1184-6; PS1186-3; PS1194-1; PS1196-1; PS1197-1; PS1198-1; PS1199-1; PS12; PS12/116; PS12/117; PS12/119; PS12/122; PS12/127; PS12/128; PS12/129; PS12/130; PS12/132; PS12/133; PS12/185; PS12/186; PS12/193; PS12/194; PS12/195; PS12/196; PS12/199; PS12/200; PS12/238; PS12/242; PS12/244; PS12/247; PS12/248; PS12/250; PS12/252; PS12/260; PS12/266; PS12/271; PS12/273+276; PS12/280; PS12/284; PS12/287; PS12/289; PS12/291; PS12/298; PS12/300; PS12/302; PS12/305; PS12/308; PS12/310; PS12/312; PS12/314; PS12/316; PS12/319; PS12/321; PS12/323; PS12/325; PS12/327; PS12/333; PS12/336; PS12/338; PS12/340; PS12/342; PS12/344; PS12/346; PS12/348; PS12/350; PS12/352; PS12/354; PS12/356; PS12/358; PS12/360; PS12/364; PS12/366; PS12/368; PS12/372; PS12/374; PS12/376; PS12/378; PS12/380; PS12/382; PS12/384; PS12/387; PS12/396; PS12/418; PS12/437; PS12/458; PS12/465; PS12/472; PS12/486; PS12/490; PS12/492; PS12/503; PS12/504; PS12/510; PS12/526; PS12/534; PS12/536; PS1200-4; PS1201-1; PS1202-1; PS1203-1; PS1204-1; PS1205-1; PS1206-1; PS1207-1; PS1207-2; PS1208-1; PS1209-1; PS1210-1; PS1211-1; PS1212-1; PS1213-1; PS1214-1; PS1215-1; PS1216-1; PS1217-1; PS1219-1; PS1220-3; PS1222-1; PS1223-1; PS1272-1; PS1273-1; PS1275-1; PS1276-1; PS1277-1; PS1278-1; PS1279-1; PS1281-1; PS1282-1; PS1333-2; PS1338-1; PS1363-3; PS1364-1; PS1366-2; PS1367-1; PS1368-1; PS1369-1; PS1370-1; PS1371-1; PS1372-2; PS1373-2; PS1374-2; PS1375-2; PS1376-2; PS1377-1; PS1378-1; PS1379-1; PS1380-1; PS1381-1; PS1382-1; PS1383-1; PS1384-1; PS1385-1; PS1386-1; PS1387-1; PS1388-1; PS1389-1; PS1390-1; PS1391-1; PS1394-1; PS1395-1; PS1396-1; PS1397-1; PS1398-2; PS1399-1; PS1400-4; PS1401-2; PS1402-2; PS1403-1; PS1405-1; PS1406-1; PS1407-1; PS1410-1; PS1411-1; PS1412-1; PS1414-1; PS1415-1; PS1416-1; PS1417-1; PS1418-1; PS1419-1; PS1420-1; PS1421-1; PS1422-1; PS1423-1; PS1424-1; PS1425-1; PS1426-1; PS1427-1; PS1428-1; PS1451-2; PS1452-1; PS1453-1; PS1454-1; PS1455-4; PS1459-4; PS1460-1; PS1471-1; PS1472-4; PS1473-1; PS1474-1; PS1475-1; PS1476-1; PS1477-1; PS1478-1; PS1479-1; PS1480-2; PS1481-2; PS1482-2; PS1483-2; PS1484-2; PS1485-1; PS1486-2; PS1487-1; PS1488-2; PS1489-3; PS1490-2; PS1491-3; PS1492-1; PS1493-2; PS1494-2; PS1495-1; PS1496-2; PS1497-1; PS1498-1; PS1499-2; PS1500-2; PS1501-1; PS1502-1; PS1505-1; PS1506-1; PS1507-2; PS1508-2; PS1509-2; PS1537-1; PS1538-1; PS1539-1; PS1540-1; PS1542-1; PS1543-1; PS1544-1; PS1545-1; PS1546-2; PS1547-1; PS1554-1; PS1555-1; PS1557-1; PS1558-1; PS1559-1; PS1560-1; PS1563-1; PS1564-1; PS1569-1; PS1572-1; PS1573-2; PS1574-1; PS1575-1; PS1575-2; PS1576-1; PS1577-2; PS1578-1; PS1579-1; PS1581-2; PS1582-1; PS1584-1; PS1585-1; PS1586-2; PS1587-1; PS1588-2; PS1589-1; PS1590-1; PS1591-2; PS1593-1; PS1594-1; PS1595-2; PS1596-1; PS1597-1; PS1598-2; PS1599-1; PS16; PS16/403; PS16/405; PS16/410; PS16/413; PS16/415; PS16/417; PS16/419; PS16/425; PS16/427; PS16/430; PS16/432; PS16/446; PS16/472; PS16/499; PS16/507; PS16/509; PS16/510; PS16/515; PS16/516; PS16/518; PS16/525; PS16/526; PS16/528; PS16/530; PS16/534; PS16/536; PS16/540; PS16/541; PS16/547; PS16/549; PS16/552; PS16/554; PS16/557; PS1600-2; PS1601-1; PS1602-1; PS1603-2; PS1604-1; PS1605-3; PS1606-1; PS1607-1; PS1608-1; PS1609-2; PS1610-3; PS1611-1; PS1612-1; PS1613-2; PS1614-1; PS1615-2; PS1616-1; PS1617-2; PS1618-2; PS1619-1; PS1620-2; PS1621-2; PS1622-1; PS1623-2; PS1624-1; PS1625-1; PS1626-1; PS1627-1; PS1628-2; PS1629-1; PS1631-1; PS1632-1; PS1635-2; PS1636-1; PS1637-1; PS1638-1; PS1639-1; PS1640-3; PS1641-1; PS1642-1; PS1643-3; PS1645-1; PS1647-2; PS1648-2; PS1787-1; PS1788-1; PS1790-2; PS1791-1; PS1792-2; PS1793-1; PS1794-2; PS1795-1; PS1796-2; PS1797-1; PS1798-2; PS18; PS18/044; PS18/048; PS18/055; PS18/056; PS18/058; PS18/059; PS18/063; PS18/065; PS18/067; PS18/075; PS18/080; PS18/081; PS18/082; PS18/083; PS18/084; PS18/086; PS18/088; PS18/092; PS18/094; PS18/096; PS18/100; PS18/101; PS18/102; PS18/106; PS18/108; PS18/114; PS18/126; PS18/127; PS18/129; PS18/135; PS18/141; PS18/142; PS18/143; PS18/144; PS18/145; PS18/146; PS18/147; PS18/148; PS18/149; PS18/150; PS18/151; PS18/152; PS18/153; PS18/154; PS18/161; PS18/165; PS18/166; PS18/167; PS18/169; PS18/170; PS18/171; PS18/172; PS18/173; PS18/175; PS18/177; PS18/178; PS18/179; PS18/180; PS18/181; PS18/182; PS18/183; PS18/184; PS18/185; PS18/186; PS18/187; PS18/189; PS18/190; PS18/191; PS18/192; PS18/193; PS18/194; PS18/196; PS18/198; PS18/199; PS18/200; PS18/201; PS18/202; PS18/203; PS18/204; PS18/208; PS18/210; PS18/211; PS18/212; PS18/214; PS18/216; PS18/217; PS18/218; PS18/219; PS18/221; PS18/222; PS18/227; PS1800-2; PS1802-2; PS1803-2; PS1805-5; PS1806-5; PS18 06AQANTIX_2; PS1807-1; PS1811-7; PS1812-5; PS1813-5; PS1817-5; PS1818-1; PS1819-5; PS1820-5; PS1821-5; PS1822-1; PS1823-1; PS1824-2; PS1825-5; PS1826-2; PS1828-2; PS1829-1; PS1831-5; PS1953-1; PS1954-1; PS1957-1; PS1958-1; PS1960-1; PS1961-1; PS1963-1; PS1964-1; PS1965-1; PS1967-
    Type: Dataset
    Format: application/zip, 3 datasets
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 4
    facet.materialart.
    Unknown
    Organic-geochemical bulk parameters and specific biomarkers of three sediment core from the Laptev Sea (1999)
    PANGAEA
    In:  Supplement to: Fahl, Kirsten; Stein, Ruediger (1999): Biomarkers as organic-carbon-source and environmental indicators in the Late Quaternary Arctic Ocean: Problems and Perspectives. Marine Chemistry, 63(3-4), 293-309, https://doi.org/10.1016/S0304-4203(98)00068-1
    Details
    Publication Date: 2024-07-01
    Description: In order to examine the variation in marine and terrigenous sources of the organic matter during the last 15,000 Cal. yr BP, hydrogen index values, C/N ratios, and specific biomolecules (short- and long-chain n-alkanes, short-chain fatty acids, sterols, alkenones, and pigments) were determined in three sediment cores from the Laptev Sea continental margin. The results show that the interpretation of the biomarker data is much more complicated and less definitive in comparison to similar data sets from low-latitude open-ocean environments. This is mainly caused by the complexity of the Arctic Ocean system, which is characterized by a high seasonality of sea-ice cover and primary productivity, sea-ice sediment transport and a high fluvial supply of freshwater (aquatic) organic matter. A combination of organic geochemical, organic petrographic and micropaleontological data may yield to a more precise identification of organic-carbon sources for these complex systems. On the Laptev Sea shelf (cores KD9502-14 and PS2725-5), terrigenous organic-carbon input controlled by river discharge seems to be predominant during the last about 10,000 Cal. yr BP. Maximum supply of terrigenous organic carbon was reached in the Early Holocene (i.e., about 9000-10,000 Cal. yr BP). Further offshore at the upper continental slope (core PS2458-4), a major change in organic-composition occurred near 10,000 Cal. yr BP. During this period hydrogen indices as well as the amounts of short-chain n-alkanes, short-chain fatty acids, dinosterol and brassicasterol significantly increased, indicating increased relative proportions of marine organic matter preserved in the later time interval.
    Keywords: Arctic Ocean; ARK-IX/4; ARK-XI/1; AWI_Paleo; Gravity corer (Kiel type); KAL; Kapitan Dranitsyn; Kasten corer; KD9502-14; Laptev Sea; Paleoenvironmental Reconstructions from Marine Sediments @ AWI; Polarstern; PS2458-4; PS27; PS27/038; PS2725-5; PS36; PS36/009; Quaternary Environment of the Eurasian North; QUEEN; SL; Transdrift-III; VC; Vibro corer
    Type: Dataset
    Format: application/zip, 5 datasets
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 5
    facet.materialart.
    Unknown
    Living benthic foraminifers from the central Arctic Ocean (1998)
    PANGAEA
    In:  Supplement to: Wollenburg, Jutta Erika; Mackensen, Andreas (1998): Living benthic foraminifers from the central Arctic Ocean: faunal composition, standing stock and diversity. Marine Micropaleontology, 34(3-4), 153-185, https://doi.org/10.1016/S0377-8398(98)00007-3
    Details
    Publication Date: 2024-07-01
    Description: Fifty short sediment cores collected with a multiple corer and five box cores from the central Arctic Ocean were analysed to study the ecology and distribution of benthic foraminifers. To work out living faunal associations, standing stock and diversity, separate analyses of living (Rose Bengal stained) and dead foraminifers were carried out for the sediment surface. The size fractions between 63 and 125 µm and 〉125 µm were counted separately to allow comparison with former Arctic studies and with studies from the adjacent Norwegian-Greenland Sea, Barents Sea and the North Atlantic Ocean. Benthic foraminiferal associations are mainly controlled by the availability of food, and competition for food, while water mass characteristics, bottom current activity, substrate composition, and water depth are of minor importance. Off Spitsbergen in seasonally ice-free areas, high primary production rates are reflected by high standing stocks, high diversities, and foraminiferal associations (〉125 µm) that are similar to those of the Norwegian-Greenland Sea. Generally, in seasonally ice-free areas standing stock and diversity increase with increasing food supply. In the central Arctic Ocean, the oligotrophic permanently ice-covered areas are dominated by epibenthic species. The limited food availability is reflected by very low standing stocks and low diversities. Most of these foraminiferal associations do not correspond to those of the Norwegian-Greenland Sea. The dominant associations include simple agglutinated species such as Sorosphaerae, Placopsilinellae, Komokiacea and Aschemonellae, as well as small calcareous species such as Stetsonia horvathi and Epistominella arctica. Those of the foraminiferal species that usually thrive under seasonally ice-free conditions in middle bathyal to lower bathyal water depth are found under permanently ice-covered conditions in water depths about 1000 m shallower, if present at all.
    Keywords: Amundsen Basin; ARK-IX/4; ARK-VIII/2; ARK-VIII/3; AWI_Paleo; Barents Sea; Gakkel Ridge, Arctic Ocean; Giant box corer; GKG; Lomonosov Ridge, Arctic Ocean; Makarov Basin; MIC; MiniCorer; Morris Jesup Rise; MUC; MultiCorer; Nansen Basin; Paleoenvironmental Reconstructions from Marine Sediments @ AWI; Polarstern; PS19/091; PS19/094; PS19/100; PS19/111; PS19/113; PS19/114; PS19/117; PS19/150; PS19/152; PS19/153; PS19/154; PS19/157; PS19/158; PS19/159; PS19/160; PS19/161; PS19/164; PS19/165; PS19/166; PS19/167; PS19/172; PS19/173; PS19/175; PS19/176; PS19/178; PS19/181; PS19/182; PS19/183; PS19/184; PS19/185; PS19/186; PS19/189; PS19/190; PS19/194; PS19/196; PS19/198; PS19/200; PS19/214; PS19/216; PS19/218; PS19/222; PS19/224; PS19/226; PS19/228; PS19/234; PS19/241; PS19/245; PS19/246; PS19/249; PS19/252; PS19 ARCTIC91; PS19 EPOS II; PS2125-1; PS2125-2; PS2127-1; PS2129-2; PS2137-1; PS2139-1; PS2140-1; PS2143-1; PS2157-3; PS2159-3; PS2160-3; PS2161-1; PS2163-1; PS2164-1; PS2165-5; PS2166-1; PS2167-3; PS2168-3; PS2170-4; PS2171-2; PS2172-3; PS2175-4; PS2176-2; PS2177-3; PS2178-4; PS2179-3; PS2180-1; PS2181-4; PS2182-4; PS2183-3; PS2184-3; PS2185-4; PS2186-3; PS2187-5; PS2190-5; PS2191-1; PS2192-2; PS2193-3; PS2198-4; PS2199-4; PS2200-4; PS2202-4; PS2204-3; PS2205-1; PS2206-4; PS2208-1; PS2210-3; PS2212-6; PS2213-4; PS2214-1; PS2214-4; PS2215-1; PS2445-2; PS2446-2; PS2447-3; PS2448-3; PS27; PS27/019; PS27/020; PS27/024; PS27/025; Quaternary Environment of the Eurasian North; QUEEN; Svalbard; Yermak Plateau
    Type: Dataset
    Format: application/zip, 5 datasets
    Location Call Number Expected Availability
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  • 6
    facet.materialart.
    Unknown
    Calcium carbonate global LGM Burial rate data (1998)
    PANGAEA
    In:  Supplement to: Catubig, Nina R; Archer, David E; Francois, Roger; deMenocal, Peter B; Howard, William R; Yu, Ein-Fen (1998): Global deep-sea burial rate of calcium carbonate during the last glacial maximum. Paleoceanography, 13(3), 298-310, https://doi.org/10.1029/98PA00609
    Details
    Publication Date: 2024-07-01
    Description: Global databases of calcium carbonate concentrations and mass accumulation rates in Holocene and last glacial maximum sediments were used to estimate the deep-sea sedimentary calcium carbonate burial rate during these two time intervals. Sparse calcite mass accumulation rate data were extrapolated across regions of varying calcium carbonate concentration using a gridded map of calcium carbonate concentrations and the assumption that accumulation of noncarbonate material is uncorrelated with calcite concentration within some geographical region. Mean noncarbonate accumulation rates were estimated within each of nine regions, determined by the distribution and nature of the accumulation rate data. For core-top sediments the regions of reasonable data coverage encompass 67% of the high-calcite (〉75%) sediments globally, and within these regions we estimate an accumulation rate of 55.9 ± 3.6 x 10**11 mol/yr. The same regions cover 48% of glacial high-CaCO3 sediments (the smaller fraction is due to a shift of calcite deposition to the poorly sampled South Pacific) and total 44.1 ± 6.0 x 10**11 mol/yr. Projecting both estimates to 100 % coverage yields accumulation estimates of 8.3 x 10**12 mol/yr today and 9.2 x 10**12 mol/yr during glacial time. This is little better than a guess given the incomplete data coverage, but it suggests that glacial deep sea calcite burial rate was probably not considerably faster than today in spite of a presumed decrease in shallow water burial during glacial time.
    Keywords: 0055PG; 0082PG; 0091PG; 113-694; 113-697; 114-699; 114-701; 114-702; 114-704; 115-708A; 115-716B; 117-722B; 117-728A; 119-737; 119-739; 119-740; 119-741; 119-742; 119-743; 119-745; 120-751A; 19-183; 19-193; 20-194; 20-195; 20-196; 21-204; 22-211; 22-213; 22-215; 26-256; 26-257; 280; 28-267; 28-268; 28-269; 28-270; 30-285; 31-290; 31-291; 31-298; 32-307; 32-311; 34-321; 5-32; 56-434; 60-452; 60-460; 60-461; 63-472; 63-473; 6-45A; 6-46; 6-52; 6-59; 7-65; 7-66; 7-67; 85-572_Site; 85-572A; 85-574; 86-576; 86-578; 86-579; 86-580; 86-581; A150/180; A152-118; A156-3; A156-4; A164-24; A164-5; A164-6; A16-46; A164-61; A16-461; A167-13; A167-14; A173-13; A173-4; A179-15; A180-15; A180-16; A180-32; A180-39; A180-47; A180-48; A180-56; A180-72; A180-73; A180-74; A180-76; A180-9; A18-39; A18-72; A18-73; A240-ML; Albatross IV (1963); Antarctic Ocean; Antarctic Ocean/BASIN; Antarctic Ocean/CONT RISE; Antarctic Ocean/PLAIN; APSARA1; APSARA2; APSARA4; Arabian Sea; AT_II-107_65; ATII_USA; Atlantic Ocean; Atlantis II (1963); BC; Box corer; CH8X; CHN82-04; CHN82-11; CHN82-15; CHN82-20; COMPCORE; Composite Core; core_59; core_60; DRILL; Drilling/drill rig; ELT14; ELT14.006-PC; ELT17; ELT17.009-PC; ELT45; ELT45.009-PC; ELT45.024-PC; ELT45.027-PC; ELT45.029-PC; ELT45.032-PC; ELT45.063-PC; ELT45.064-PC; ELT45.071-PC; ELT45.074-PC; ELT48; ELT48.003-PC; ELT48.006-PC; ELT48.011-PC; ELT48.013-PC; ELT48.022-PC; ELT48.027-PC; ELT48.029-PC; ELT49; ELT49.008-PC; ELT49.017-PC; ELT49.018-PC; ELT49.021-PC; ELT49.023-PC; ELT50; ELT50.013-PC; ELT50.017-PC; Eltanin; EN06601; EN066-10GGC; EN066-16GGC; EN066-17GGC; EN066-21GGC; EN066-23PG; EN066-24PG; EN066-26GGC; EN066-29GGC; EN066-32GGC; EN066-36GGC; EN066-39GGC; EN066-39PG; EN066-43GGC; EN066-44GGC; EN066-47PG; EN77-29; Endeavor; ENXX; Equatorial Pacific; ERDC; ERDC-079BX; ERDC-092BX; ERDC-102BX; ERDC-129BX; GC; Glomar Challenger; Gravity corer; IC-5; India; Indian Ocean; Indian Ocean//BASIN; IO1578-4; Jean Charcot; Joides Resolution; KN11002; KN708-1; Knorr; KNR110-55; KNR110-82; KNR110-91; KS7703; Lakshadweep Sea; Leg113; Leg114; Leg115; Leg117; Leg119; Leg120; Leg19; Leg20; Leg21; Leg22; Leg26; Leg28; Leg30; Leg31; Leg32; Leg34; Leg5; Leg56; Leg6; Leg60; Leg63; Leg7; Leg85; Leg86; Marion Dufresne (1972); MD13; MD38; MD77-202; MD82-424; MD84-527; MD84-529; MD84-551; MD84-552; MD84-562; MD88-769; MD88-770; MD88-773; MD88-787; Melville; MN76-01, Pleiades; NGR9; NODC-0418; North Atlantic; North Pacific; North Pacific/ABYSSAL FLOOR; North Pacific/BASIN; North Pacific/CONT RISE; North Pacific/Gulf of California/CONT RISE; North Pacific/Philippine Sea/RIDGE; North Pacific/Philippine Sea/TRENCH; North Pacific/Philippine Sea/TROUGH; North Pacific/PLAIN; North Pacific/PLATEAU; North Pacific/RIDGE; North Pacific/SEAMOUNT; North Pacific/SEDIMENT POND; North Pacific/TRENCH; North Pacific/TROUGH; off NW Africa; OSIRIS III; Pacific Ocean; PC; Piston corer; PLDS-130P; PLDS-130PG; PLDS-4; Prydz Bay; RAMA; RAMA03WT; RAMA-44P; RC01; RC0101-RC0102; RC01-2; RC08; RC08-145; RC08-18; RC08-39; RC08-43; RC08-48; RC08-63; RC08-71; RC08-78; RC08-79; RC08-89; RC08-92; RC08-94; RC09; RC09-110; RC09-124; RC09-126; RC09-129; RC09-139; RC09-161; RC09-162; RC09-225; RC09-49; RC10; RC10-139; RC10-140; RC10-159; RC10-160; RC10-161; RC10-171; RC10-179; RC10-181; RC10-182; RC10-203; RC10-206; RC10-216; RC10-288; RC10-289; RC10-50; RC10-97; RC11; RC11-114; RC11-118; RC11-119; RC1112; RC11-120; RC11-121; RC11-170; RC11-171; RC11-172; RC11-179; RC11-193; RC11-195; RC11-209; RC11-21; RC11-210; RC11-213; RC11-220; RC11-230; RC11-26; RC11-76; RC11-77; RC11-78; RC11-80; RC11-83; RC11-86; RC11-91; RC11-94; RC11-96; RC11-97; RC12; RC12-103; RC12-107; RC12-109; RC12-121; RC12-176; RC12-179; RC12-225; RC12-227; RC12-234; RC12-241; RC12-267; RC12-289; RC12-291; RC12-294; RC12-328; RC12-340; RC12-341; RC12-343; RC12-344; RC12-361; RC12-401; RC12-412; RC12-413; RC12-416; RC12-419; RC12-63; RC12-65; RC12-66; RC13; RC13-113; RC13-151; RC13-152; RC13-153; RC13-159; RC13-189; RC13-190; RC13-205; RC13-210; RC13-227; RC13-228; RC13-229; RC13-243; RC13-251; RC13-253; RC13-254; RC13-255; RC13-256; RC13-259; RC13-261; RC13-263; RC13-271; RC13-273; RC13-275; RC13-38; RC13-63; RC13-81; RC14; RC14-106; RC14-11; RC14-29; RC14-35; RC14-39; RC14-7; RC14-9; RC14-99; RC15; RC15-23; RC15-52; RC15-61; RC15-93; RC15-94; RC15-98; RC17; RC17-113; RC17-184; RC17-194; RC17-196; RC17-197; RC17-60; RC17-61; RC17-63; RC17-69; RC17-73; RC17-98; RC23; RC23-50BX1; RC23-52BX1; RC23-53BX1; RC23-54BX1; RC23-61BX1; RE05; RE05-34; RE05-36; RE05-54; RE5-034; RE5-036; RE5-054; Rehoboth; RIVER; Robert Conrad; Sampling river; SDSE_090; SDSE_092; South Atlantic; South Atlantic Ocean; Southern East Pacific Rise; South Indian Ocean; South Indian Ridge, South Indian Ocean; South Pacific; South Pacific/BASIN; South Pacific/TRENCH; SP8-4; SwedishDeepSeaExpedition; TC; Thomas Washington; Trigger corer; V04; V04-1; V04-32; V04-8; V12; V12-122; V14; V14-101; V14-102; V14-77; V14-81; V15; V15-157; V15-168; V16; V16-114; V16-115; V16-122; V16-205; V16-25; V16-36; V17; V17-165; V17-178; V17-42; V17-43; V17-44; V18; V18-110; V18-222; V18-312; V18-318; V18-337; V18-68; V19; V19-178; V19-185; V19-188; V19-19; V19-201; V19-202; V19-204; V19-21; V19-240; V19-248; V19-25; V19-27; V19-28; V19-281; V19-282; V19-283; V19-291; V19-30; V19-305; V19-309; V19-41; V19-53; V19-55; V19-65; V19-96; V20; V20-102; V20-103; V20-104; V20-105; V20-107; V20-108; V20-109; V20-119; V20-121; V20-122; V20-123; V20-124; V20-126; V20-129; V20-170; V20-175; V20-212; V20-227; V20-228; V20-241; V20-242; V20-68; V20-74; V20-79; V20-81; V20-82; V20-85; V20-86; V20-87; V20-88; V20-92; V20-95; V20-96; V20-97; V20-98; V21; V21-145; V21-146; V21-148; V21-150; V21-151; V21-171; V21-173; V21-174; V21-175; V21-178; V21-212; V21-214; V21-29; V21-30; V21-33; V21-59; V22; V22-108; V22-168; V22-171; V22-172; V22-174; V22-177; V22-182; V22-186; V22-188; V22-196; V22-197; V22-219; V22-222; V22-234; V22-26; V22-38; V22-83; V22-86; V23; V23-100; V23-145; V23-23; V23-42; V23-58; V23-59; V23-60; V23-73; V23-74; V23-81; V23-82; V23-83; V23-84; V23-91; V23-98; V24; V24-1; V24-109; V24-166; V24-203; V24-221; V24-229; V24-235; V24-237; V24-240; V24-55; V24-58; V24-59; V24-62; V25; V25-21; V25-42; V25-44; V25-56; V25-59; V25-60; V25-75; V26; V26-104; V26-175; V26-176; V26-177; V26-37; V26-41; V26-46; V26-63; V26-82; V27; V27-110; V27-116; V27-17; V27-171; V27-175; V27-178; V27-19; V27-20; V27-221; V27-228; V27-232; V27-238; V27-239; V27-240; V27-248; V27-263; V27-264; V27-265; V27-267; V27-269; V27-46; V27-47; V27-60; V27-84; V27-85; V27-86; V28; V28-108; V28-129; V28-14; V28-177; V28-179; V28-185; V28-203; V28-229; V28-230; V28-235; V28-238; V28-239; V28-249; V28-255; V28-294; V28-304; V28-35; V28-38; V28-56; V28-59; V28-89; V29; V29-105; V29-144; V29-15; V29-153; V29-172; V29-173; V29-174; V29-177; V29-178; V29-179; V29-180; V29-183; V29-192; V29-206; V29-210; V29-219; V29-29; V29-30; V29-48; V29-84; V29-86; V29-87; V29-89; V29-90; V30; V30-100; V30-101; V30-36; V30-40; V30-41; V30-41k; V30-49; V30-51; V30-51k; V30-88; V30-93; V30-96; V30-97; V30-99; V31; V31-166; V31-178; V32; V32-102; V32-109; V32-126; V32-8; V34; V34-101; V34-109; V34-111; V34-34; V34-48; V34-51; V34-53; V34-54; V34-55; V34-87; V34-89; V34-91; V34-92; Vema; VNTR01; VNTR01-49GC; W12; W26; W48K; W53K; W8402A; W8402A-14; W8709A; W8709A-1; W8709A-13; W8709A-8; W8803B; W8803B-51GC; WAH-8-2; Wecoma; Weddell Sea; WW21; X164021; X164032; X164041; X164051; X164061; X164071; X164081; X164101; X164111; X164121; X164131; X164151; X164161; X164171; X164222; X164241; X164251; X164263; X164282; X164291; X164301; X164311; X164321; Y70-5; Y70-5-64; Yaquina
    Type: Dataset
    Format: application/zip, 4 datasets
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 7
    facet.materialart.
    Unknown
    Data compilation of ESOP (1998)
    PANGAEA
    In:  International Council for the Exploration of the Sea, Copenhagen
    Details
    Publication Date: 2024-07-01
    Description: The work in this sub-project of ESOP focuses on the advective and convective transforma-tion of water masses in the Greenland Sea and its neighbouring areas. It includes observational work on the sub-mesoscale and analysis of hydrographic data up to the gyre-scale. Observations of active convective plumes were made with a towed chain equipped with up to 80 CTD sensors, giving a horizontal and vertical resolution of the hydrographic fields of a few metres. The observed scales of the penetrative convective plumes compare well with those given by theory. On the mesoscale the structure of homogeneous eddies formed as a result of deep convection was observed and the associated mixing and renewal of the intermediate layers quantified. The relative importance and efficiency of thermal and haline penetrative convection in relation to the surface boundary conditions (heat and salt fluxes and ice cover) and the ambient stratification are studied using the multi year time series of hydro-graphic data in the central Greenland Sea. The modification of the water column of the Greenland Sea gyre through advection from and mixing with water at its rim is assessed on longer time scales. The relative contributions are quantified using modern water mass analysis methods based on inverse techniques. Likewise the convective renewal and the spreading of the Arctic Intermediate Water from its formation area is quantified. The aim is to budget the heat and salt content of the water column, in particular of the low salinity surface layer, and to relate its seasonal and interannual variability to the lateral fluxes and the fluxes at the air-sea-ice interface. This will allow to estimate residence times for the different layers of the Greenland Sea gyre, a quantity important for the description of the Polar Ocean carbon cycle.
    Keywords: 1; 10; 101; 11; 12; 13; 14; 15; 16; 162; 17; 18; 19; 2; 20; 21; 22; 23; 24; 25; 26; 262; 27; 28; 29; 3; 30; 31; 32; 33; 34; 35; 36; 362; 37; 38; 39; 4; 40; 41; 42; 43; 44; 45; 46; 462; 47; 48; 49; 5; 50; 51; 52; 53; 54; 55; 56; 57; 58; 59; 6; 60; 61; 62; 63; 64; 65; 66; 67; 68; 69; 7; 70; 71; 72; 73; 74; 75; 76; 77; 78; 79; 8; 80; 81; 82; 83; 84; 85; 87; 88; 89; 9; 90; 91; 92; 93; ARK-XIII/3; B02/98; B02/98-1001; B02/98-1011; B02/98-1021; B02/98-1031; B02/98-1061; B02/98-1062; B02/98-1071; B02/98-1081; B02/98-1101; B02/98-1111; B02/98-1121; B02/98-1131; B02/98-1141; B02/98-1151; B02/98-1181; B02/98-1191; B02/98-1221; B02/98-1222; B02/98-1231; B02/98-1241; B02/98-1251; B02/98-1261; B02/98-1271; B02/98-1281; B02/98-1291; B02/98-1292; B02/98-1293; B02/98-1301; B02/98-1311; B02/98-1321; B02/98-1361; B02/98-1371; B02/98-1381; B02/98-1391; B02/98-1401; B02/98-1411; B02/98-1421; B02/98-1431; B02/98-1441; B02/98-1451; B02/98-1461; B02/98-1471; B02/98-1481; B02/98-1491; B02/98-1501; B02/98-1511; B02/98-1521; B02/98-1531; B02/98-1541; B02/98-1551; B02/98-1561; B02/98-1571; B02/98-1581; B02/98-1591; B02/98-1601; B02/98-1611; B02/98-1622; B02/98-531; B02/98-541; B02/98-551; B02/98-561; B02/98-571; B02/98-581; B02/98-591; B02/98-601; B02/98-621; B02/98-622; B02/98-631; B02/98-641; B02/98-651; B02/98-661; B02/98-671; B02/98-681; B02/98-691; B02/98-701; B02/98-711; B02/98-721; B02/98-731; B02/98-751; B02/98-761; B02/98-771; B02/98-781; B02/98-791; B02/98-801; B02/98-811; B02/98-821; B02/98-831; B02/98-843; B02/98-845; B02/98-851; B02/98-861; B02/98-891; B02/98-901; B02/98-911; B02/98-921; B02/98-931; B02/98-941; B02/98-961; B02/98-971; B02/98-972; B02/98-973; B02/98-981; B02/98-991; B03/97; B03/97-531; B03/97-532; B03/97-551; B03/97-552; B03/97-711; B03/97-712; B03/97-751; B03/97-752; B03/97-753; B03/97-771; B03/97-772; B03/97-781; B03/97-782; B03/97-931; B03/97-932; B05/96; B05/96-1252; B05/96-252; B05/96-253; B05/96-254; B05/96-263; B05/96-278; B05/96-293-2; B06/97; B06/97-1431; B06/97-1441; B06/97-1451; B06/97-1461; B06/97-1471; B06/97-1481; B06/97-1492; B06/97-1501; B06/97-1511; B06/97-1512; B06/97-1513; B06/97-1521; B06/97-1531; B06/97-1541; B06/97-1551; B06/97-1561; B06/97-1571; B06/97-1581; B06/97-1591; B06/97-1601; B06/97-1611; B06/97-1621; B06/97-1631; B06/97-1643; B06/97-1644; B06/97-1651; B06/97-1661; B06/97-1671; B06/97-1681; B06/97-1691; B06/97-1701; B06/97-1711; B06/97-1721; B06/97-1731; B06/97-1741; B06/97-1751; B06/97-1761; B06/97-1772; B06/97-1773; B06/97-1781; B06/97-1791; B06/97-1801; B06/97-1811; B06/97-1821; B06/97-1831; B06/97-1841; B06/97-1851; B06/97-1861; B06/97-1871; B06/97-1881; B06/97-1891; B06/97-1901; B06/97-1911; B06/97-1912; B06/97-1921; B06/97-1931; B06/97-1941; B06/97-1951; B06/97-1971; B06/97-1981; B06/97-1991; B06/97-2001; B06/97-2011; B06/97-2021; B06/97-2031; B06/97-2041; B06/97-2051; B06/97-2061; B06/97-2071; B06/97-2081; B06/97-2091; B06/97-2101; B06/97-2121; B06/97-2122; B06/97-2131; B06/97-2141; B06/97-2142; B06/97-2151; B06/97-2161; B06/97-2171; B06/97-2181; B06/97-2191; B06/97-2211; B06/97-2221; B06/97-2231; B06/97-2241; B06/97-2251; B06/97-2261; B06/97-2271; B06/97-2281; B06/97-2291; B06/97-2301; B06/97-2311; B06/97-2321; B06/97-2331; B06/97-2341; B06/97-2351; B06/97-2361; B06/97-2371; B06/97-2381; B06/97-2391; B06/97-2401; B06/97-2411; B06/97-2421; B06/97-2431; B06/97-2441; B06/97-2451; B06/97-2461; B06/98; B06/98-2531; B06/98-2541; B06/98-2551; B06/98-2561; B06/98-2571; B06/98-2581; B06/98-2582; B06/98-2591; B06/98-2592; B06/98-2601; B06/98-2611; B06/98-2612; B06/98-2621; B06/98-2631; B06/98-2641; B06/98-2642; B06/98-2651; B06/98-2652; B06/98-2661; B06/98-2671; B06/98-2672; B06/98-2681; B06/98-2691; B06/98-2701; B06/98-2711; B06/98-2721; B06/98-2741; B06/98-2751; B06/98-2761; B06/98-2771; B06/98-2781; B06/98-2791; B06/98-2801; B06/98-2811; B06/98-2821; B06/98-2831; B06/98-2841; B06/98-2851; B06/98-2861; B06/98-2871; B06/98-2881; B06/98-2891; B06/98-2901; B06/98-2911; B06/98-2921; B06/98-2931; B06/98-2941; B06/98-2951; B06/98-2961; B06/98-2971; B06/98-2981; B06/98-2991; B06/98-3001; B06/98-3002; B06/98-3003; B06/98-3004; B06/98-3011; B06/98-3012; B06/98-3021; B06/98-3031; B06/98-3041; B06/98-3051; B06/98-3081; B06/98-3101; B06/98-3102; B06/98-3103; B06/98-3104; B06/98-3121; B06/98-3141; B06/98-3142; B06/98-3143; B06/98-3144; B06/98-3161; B06/98-3171; B06/98-3181; B06/98-3191; B06/98-3201; B06/98-3211; B06/98-3221; B06/98-3231; B06/98-3241; B06/98-3251; B06/98-3261; B06/98-3271; B06/98-3321; B06/98-3331; B06/98-3341; B06/98-3351; B06/98-3361; B06/98-3371; B06/98-3381; B06/98-3391; B06/98-3401; B06/98-3441; B06/98-3451; B06/98-3461; B06/98-3481; B06/98-3482; B06/98-3483; B06/98-3511; B06/98-3522; B06/98-3531; B06/98-3541; B06/98-3551; B06/98-3561; B06/98-3581; B06/98-3591; B06/98-3611; B06/98-3621; B06/98-3631; B06/98-3641; B06/98-3651; B06/98-3661; B06/98-3671; B06/98-3681; B06/98-3691; B06/98-3701; B06/98-3711; B06/98-3731; B06/98-3741; B06/98-3751; B06/98-3761; B06/98-3771; B06/98-3781; B06/98-3791; B09/96; B09/96-5311; B09/96-5312; B09/96-5321; B09/96-5322; B09/96-5351; B09/96-5352; B09/96-5353; B09/96-5451; B09/96-5452; B09/96-5481; B09/96-5482; B09/96-5511; B09/96-5512; B09/96-5521; B09/96-5522; B09/96-5531; B09/96-5532; B09/98; B09/98-5432; B09/98-5433; B09/98-5434; B09/98-5441; B09/98-5451; B09/98-5461; B09/98-5471; B09/98-5481; B09/98-5491; B09/98-5501; B09/98-5511; B09/98-5531; B09/98-5541; B09/98-5551; B09/98-5561; B09/98-5581; B09/98-5601; B09/98-5631; B09/98-5641; B09/98-5651; B09/98-5661; B09/98-5671; B09/98-5681; B09/98-5711; B09/98-5731; B09/98-5732; B09/98-5741; B09/98-5751; B09/98-5771; B09/98-5791; B09/98-5792; B09/98-5801; B09/98-5804; B09/98-5805; B10/97; B10/97-3601; B10/97-3602; B10/97-3851; B10/97-3871; B10/97-3881; B10/97-3891; B10/97-3892; B10/97-3911; B10/97-3912; B10/97-3921; B10/97-3922; B10/97-3923; B10/97-3931; B10/97-3932; B10/97-3941; B10/97-4011; B10/97-4012; B10/97-4031; B10/97-4032; B10/97-4041; B10/97-4042; B12/96; B12/96-7210; B12/96-7220; B12/96-7230; B12/96-7240; B12/96-8520; B12/96-8540; B12/96-8550; B12/98; B12/98-7811; B12/98-7812; B12/98-7813; B12/98-8391; B12/98-8392; B12/98-8393; B12/98-8394; B12/98-8621; B12/98-8622; B15/97; B15/97-6761; B15/97-6771; B15/97-6781; B15/97-6791; B15/97-6801; B15/97-6811; B15/97-6821; B15/97-6831; B15/97-6841; B15/97-6851; B15/97-6861; B15/97-6871; B15/97-6881; B15/97-6891; B15/97-6892; B15/97-6901; B15/97-6902; B15/97-6912; B15/97-6921; B15/97-6931; B15/97-6951; B15/97-6961; B15/97-6971; B15/97-6981; B15/97-6991; B15/97-7001; B15/97-7011; B15/97-7021; B15/97-7031; B15/97-7041; B15/97-7051; B15/97-7061; B15/97-7071; B15/97-7081; B15/97-7091; B15/97-7101; B15/97-7111; B15/97-7121; B15/97-7131; B15/97-7141; B15/97-7151; B15/97-7161; B15/97-7171; B15/97-7181; B15/97-7182; B15/97-7191; B15/97-7201; B15/97-7211; B15/97-7221; B15/97-7231; B15/97-7241; B15/97-7251; B15/97-7261; B15/97-7271; B15/97-7281; B15/97-7291; B15/97-7301; B15/97-7311; B15/97-7321; B15/97-7331; B15/97-7341; B15/97-7351; B15/97-7361; B15/97-7371; B15/97-7381; B15/97-7391; B15/97-7401; B15/97-7411; B15/97-7421; B15/97-7431; B15/97-7441; B15/97-7451; B15/97-7461; B15/97-7471; B15/97-7481; B15/97-7491; B15/97-7501; B15/97-7511; B15/97-7512; B15/97-7513; B15/97-7521; B15/97-7531; B15/97-7532; B15/97-7533; B15/97-7541; B15/97-7551; B15/97-7561; B15/97-7571; B15/97-7581; B15/97-7591; B15/97-7601; B15/97-7611; B15/97-7621; B15/97-7631; B15/97-7641; B15/97-7651; B15/97-7661; B15/97-7671; B15/97-7681; B15/97-7691; B15/97-7692; B15/97-7701; B15/97-7711; B15/97-7721; B15/97-7731; B15/97-7741; B15/97-7751; Bjarni Saemundsson; CARDEEP1/93; CARDEEP1/93-161; CARDEEP1/93-162; CARDEEP1/93-171; CARDEEP1/93-181; CARDEEP1/93-182; CARDEEP1/93-201; CARDEEP1/93-211; CARDEEP1/93-212; CARDEEP1/93-231; CARDEEP1/93-232; CARDEEP1/93-261; CARDEEP1/93-271; CARDEEP1/93-281; CARDEEP1/93-291; CARDEEP1/93-301; CARDEEP1/93-311; CARDEEP1/93-312; CARDEEP1/93-331; CARDEEP1/93-341; CARDEEP1/93-351; CARDEEP1/93-361;
    Type: Dataset
    Format: application/zip, 51 datasets
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 8
    facet.materialart.
    Unknown
    Physical oceanography on yearly cruises to the central Greenland Sea between 1993 and 1996 (1998)
    PANGAEA
    In:  Supplement to: Budéus, Gereon; Schneider, Wolfgang; Krause, Gunther (1998): Winter convective events and bottom water warming in the Greenland Sea. Journal of Geophysical Research: Oceans, 103(C9), 18513-18527, https://doi.org/10.1029/98JC01563
    Details
    Publication Date: 2024-07-01
    Description: From observations on yearly cruises to the central Greenland Sea between 1993 and 1996, conclusions are drawn with respect to winter convection and bottom water renewal. The data indicate that winter convection was extremely weak after 1993, not even ventilating the intermediate waters. This is remarkable, since the salinities in the upper layers increased considerably between 1993 and 1995, thus providing presumably favorable conditions for winter convection. With the absence of deep reaching winter convective events, the temperatures in the deeper waters of the Greenland Gyre increased steadily by about 0.03 K between 1993 and 1996. We conclude from the development of mainly the thermal structure on a zonal transect that an explanation for the temperature increase can be given by a large-scale downward water movement of about 150 m/yr in the central Greenland Sea. The data indicate that this process is independent of changes in the dynamically induced density distribution. It is therefore possible that a downward movement, perhaps masked by other processes, may continue for many years. If this is the case, resulting flushing times would be of the order of 20-30 years only. The presence of a large-scale circulation cell with downward movement in the central Greenland Gyre would explain the observed warming of the bottom waters without the demand for an actually active heat source. It is also in accordance with the observed increase of chemical tracer concentrations in the deep waters.
    Keywords: ARK-IX/1b; ARK-X/1; ARK-XI/2; AWI_PhyOce; CTD/Rosette; CTD-RO; ESOP; European subpolar ocean programme : sea ice-ocean interactions; JGOFS; Joint Global Ocean Flux Study; MULT; Multiple investigations; North Greenland Sea; Norwegian Sea; Petr Kottsov; Physical Oceanography @ AWI; PK-ARK-XII; PK-XII/01-1; PK-XII/01-2; PK-XII/02; PK-XII/03; PK-XII/04; PK-XII/05; PK-XII/06; PK-XII/07; PK-XII/08-1; PK-XII/08-2; PK-XII/09; PK-XII/10; PK-XII/11; PK-XII/12; PK-XII/13; PK-XII/14; PK-XII/15; PK-XII/16; PK-XII/17; PK-XII/18; PK-XII/19; PK-XII/20; PK-XII/21; PK-XII/22; PK-XII/23; PK-XII/24; PK-XII/25; PK-XII/26; PK-XII/27; PK-XII/28; PK-XII/29; PK-XII/33; PK-XII/34; PK-XII/35; PK-XII/36; PK-XII/37; PK-XII/38; PK-XII/39; PK-XII/40; PK-XII/41; PK-XII/42; PK-XII/43; PK-XII/44; PK-XII/45; PK-XII/46; PK-XII/47; PK-XII/48; PK-XII/49; PK-XII/50; PK-XII/51; PK-XII/52; Polarstern; PS24; PS24/036; PS24/037; PS24/038; PS24/039; PS24/040; PS24/041; PS24/043; PS24/044; PS24/045; PS24/046; PS24/047; PS24/048; PS24/049; PS24/050; PS24/051; PS24/053; PS24/054; PS24/055; PS24/056; PS24/057; PS24/061; PS24/062; PS24/063; PS24/064; PS24/065; PS24/066; PS24/067; PS24/068; PS24/069; PS24/070; PS31; PS31/026; PS31/026a; PS31/027; PS31/028; PS31/029; PS31/030; PS31/031; PS31/032; PS31/033; PS31/034; PS31/035; PS31/036; PS31/037; PS31/038; PS31/039; PS31/040; PS31/041; PS31/042; PS31/043; PS31/044; PS31/045; PS31/046; PS31/048; PS31/049; PS31/050; PS31/051; PS31/052; PS31/053; PS31/054; PS31/055; PS31/056; PS31/057; PS31/058; PS31/059; PS31/060; PS31/061; PS31/062; PS31/063; PS31/064; PS31/065; PS31/066; PS31/067; PS31/068; PS31/069; PS31/070; PS31/071; PS31/072; PS31/073; PS31/074; PS31/075; PS31/076; PS31/077; PS31/078; PS31/079; PS31/080; PS31/081; PS31/082; PS31/083; PS31/084; PS31/085; PS31/087; PS31/089; PS31/090; PS31/091; PS31/092; PS31/093; PS31/094; PS31/095; PS31/096; PS31/096a; PS31/097; PS31/098; PS31/099; PS31/100; PS31/101; PS31/102; PS31/103; PS31/104; PS31/105; PS31/106; PS31/107; PS31/108; PS31/109; PS31/110; PS31/111; PS37; PS37/001-1; PS37/006-1; PS37/006-2; PS37/008-2; PS37/008-4; PS37/010; PS37/014-3; PS37/014-4; PS37/015; PS37/016-4; PS37/016-5; PS37/017; PS37/018; PS37/019; PS37/020-6; PS37/020-7; PS37/021-3; PS37/021-4; PS37/022-3; PS37/022-4; PS37/023; PS37/024; PS37/025-1; PS37/025-2; PS37/026-1; PS37/026-2; PS37/028; PS37/029; PS37/033; PS37/035; PS37/036; PS37/037; PS37/038; PS37/039; PS37/040; PS37/041; PS37/042; PS37/043; PS37/044; PS37/045; PS37/046; PS37/047; PS37/048; PS37/049; PS37/050; PS37/052; PS37/053; PS37/056; PS37/057; PS37/058; PS37/059; PS37/060; PS37/061; PS37/062; PS37/063; PS37/064; PS37/065; PS37/066; PS37/067; PS37/068; PS37/069; PS37/070; PS37/071; PS37/072; PS37/073; PS37/074; PS37/075; PS37/076; PS37/077; PS37/078; PS37/079; PS37/080; PS37/081; PS37/082; PS37/083; PS37/084; PS37/085; PS37/086; PS37/087; PS37/088; PS37/089; PS37/090; PS37/091; PS37/092; PS37/093; PS37/094; PS37/095; PS37/096; PS37/097; PS37/098; PS37/099; PS37/100; PS37/101; PS37/102; PS37/103; PS37/104; PS37/105; PS37/106; PS37/107; PS37/108; PS37/109; PS37/110; PS37/111; PS37/112; PS37/113; PS37/114; PS37/115; PS37/116; PS37/117
    Type: Dataset
    Format: application/zip, 4 datasets
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 9
    facet.materialart.
    Unknown
    Estimation of sea surface temperature from sediment core PS1768-8 (1998)
    PANGAEA
    In:  Supplement to: Zielinski, Ulrich; Gersonde, Rainer; Sieger, Rainer; Fütterer, Dieter K (1998): Quaternary surface water temperature estimations: calibration of a diatom transfer funtion for the Southern Ocean. Paleoceanography, 13(4), 365-383, https://doi.org/10.1029/98PA01320
    Details
    Publication Date: 2024-07-01
    Description: The quantitative diatom analysis of 218 surface sediment samples recovered in the Atlantic and western Indian sector of the Southern Ocean is used to define a base of reference data for paleotemperature estimations from diatom assemblages using the Imbrie and Kipp transfer function method. The criteria which justify the exclusion of samples and species out of the raw data set in order to define a reference database are outlined and discussed. Sensitivity tests with eight data sets were achieved evaluating the effects of overall dominance of single species, different methods of species abundance ranking, and no-analog conditions (e.g., Eucampia Antarctica) on the estimated paleotemperatures. The defined transfer functions were applied on a sediment core from the northern Antarctic zone. Overall dominance of Fragilariopsis kerguelensis in the diatom assemblages resulted in a close affinity between paleotemperature curve and relative abundance pattern of this species downcore. Logarithmic conversion of counting data applied with other ranking methods in order to compensate the dominance of F. kerguelensis revealed the best statistical results. A reliable diatom transfer function for future paleotemperature estimations is presented.
    Keywords: Adelaide Island; Agulhas Basin; Agulhas Ridge; Antarctic Peninsula; ANT-II/3; ANT-II/4; ANT-III/3; ANT-IV/3; ANT-IV/4; ANT-IX/2; ANT-IX/4; ANT-V/4; ANT-VI/2; ANT-VI/3; ANT-VIII/3; ANT-VIII/5; ANT-X/4; ANT-X/5; ANT-XI/2; ANT-XI/4; Argentine Islands; Atka Bay; Atlantic Indik Ridge; Atlantic Ridge; AWI_Paleo; Barents Sea; Bransfield Strait; Camp Norway; Cape Basin; Cape Fiske; Conrad Rise; Cosmonauts Sea; CTD/Rosette; CTD-RO; Drake Passage; Elephant Island; Filchner Shelf; Filchner Trough; Giant box corer; GKG; Gould Bay; Gravity corer (Kiel type); Halley Bay; Indian-Antarctic Ridge; Islas Orcadas; Joinville Island; Kapp Norvegia; King George Island, Antarctic Peninsula; Lyddan Island; Maud Rise; Meteor Rise; MIC; MiniCorer; MUC; MultiCorer; Paleoenvironmental Reconstructions from Marine Sediments @ AWI; Polarstern; PS04; PS04/247; PS04/248; PS04/249; PS04/250; PS04/261; PS04/263; PS04/264; PS04/265; PS04/266; PS04/268; PS04/269; PS04/270; PS04/271; PS04/277; PS04/302; PS04/304; PS04/331; PS04/335; PS04/346; PS04/351; PS04/380; PS04/414; PS04/423; PS04/429; PS04/433; PS04/440; PS04/447; PS04/472; PS04/508; PS04/509; PS04/540; PS06/289; PS06/303; PS06/304; PS06/311; PS06/313; PS06 SIBEX; PS08; PS08/321; PS08/324; PS08/327; PS08/333; PS08/338; PS08/344; PS08/345; PS08/346; PS08/347; PS08/350; PS08/356; PS08/357; PS08/358; PS08/359; PS08/360; PS08/361; PS08/365; PS08/366; PS08/367; PS08/368; PS08/369; PS08/374; PS08/375; PS08/379; PS08/380; PS08/381; PS08/382; PS08/384; PS08/385; PS08/386; PS08/387; PS08/396; PS08/397; PS08/401; PS08/402; PS08/410; PS08/440; PS08/445; PS08/452; PS08/480; PS08/482; PS08/483; PS08/585; PS08/601; PS08/607; PS08/610; PS08/621; PS08/627; PS10; PS10/672; PS10/675; PS10/684; PS10/686; PS10/699; PS10/701; PS10/703; PS10/707; PS10/820; PS1160-2; PS1161-1; PS1162-1; PS1163-2; PS1174-2; PS1176-3; PS1177-3; PS1178-4; PS1179-1; PS1181-2; PS1182-2; PS1183-4; PS1184-6; PS1190-1; PS1192-1; PS1193-2; PS1195-2; PS1197-1; PS1199-1; PS12; PS12/116; PS12/119; PS12/122; PS12/127; PS12/128; PS12/129; PS12/186; PS12/195; PS12/196; PS12/199; PS12/250; PS12/545; PS12/551; PS12/553; PS12/557; PS1200-4; PS1204-1; PS1207-1; PS1208-1; PS1209-1; PS1210-1; PS1211-1; PS1212-1; PS1214-1; PS1222-1; PS1223-1; PS1225-2; PS1273-1; PS1277-1; PS1278-1; PS1281-1; PS1282-1; PS1363-3; PS1364-1; PS1366-2; PS1367-1; PS1370-1; PS1372-2; PS1373-2; PS1374-2; PS1375-2; PS1376-2; PS1380-1; PS1381-1; PS1382-1; PS1383-1; PS1384-1; PS1385-1; PS1387-1; PS1388-1; PS1389-1; PS1390-1; PS1391-1; PS1394-1; PS1395-1; PS1396-1; PS1397-1; PS1398-2; PS1399-1; PS1400-4; PS1401-2; PS1402-2; PS1403-1; PS1406-1; PS1407-1; PS1410-1; PS1411-1; PS1412-1; PS1419-1; PS1421-1; PS1424-1; PS1425-1; PS1427-1; PS1428-1; PS1452-1; PS1453-1; PS1454-1; PS1455-4; PS1459-4; PS1460-1; PS1472-4; PS1474-1; PS1477-1; PS1478-1; PS1483-2; PS1484-2; PS1485-1; PS1486-2; PS1508-2; PS1537-2; PS1539-1; PS1540-1; PS1542-1; PS1543-1; PS1544-1; PS1555-1; PS1559-1; PS1560-1; PS1563-1; PS1576-1; PS16; PS16/267; PS16/271; PS16/281; PS16/284; PS16/294; PS16/303; PS16/306; PS16/311; PS16/316; PS16/321; PS16/323; PS16/329; PS16/334; PS16/337; PS16/342; PS16/345; PS16/351; PS16/354; PS16/362; PS16/366; PS16/372; PS16/403; PS16/419; PS16/425; PS16/432; PS16/446; PS16/472; PS16/499; PS1649-1; PS1651-2; PS1652-1; PS1654-1; PS1751-2; PS1752-5; PS1755-1; PS1756-6; PS1759-1; PS1764-2; PS1765-1; PS1768-1; PS1768-8; PS1771-4; PS1772-6; PS1773-2; PS1774-1; PS1775-5; PS1776-6; PS1777-7; PS1778-1; PS1779-3; PS1780-1; PS1782-6; PS1783-1; PS1786-2; PS1787-1; PS1794-2; PS1795-1; PS1798-2; PS18; PS18/059; PS18/075; PS18/084; PS18/088; PS18/092; PS18/094; PS18/096; PS18/100; PS18/106; PS18/114; PS18/118; PS18/229; PS18/231; PS18/232; PS18/236; PS18/237; PS18/238; PS18/244; PS18/249; PS18/251; PS18/253; PS18/254; PS18/257; PS18/260; PS18/261; PS18/262; PS18/263; PS18/266; PS18/267; PS1800-2; PS1802-2; PS1803-2; PS18 06AQANTIX_2; PS1961-1; PS1967-1; PS1973-1; PS1975-1; PS1977-1; PS1978-1; PS1979-1; PS1981-1; PS1985-1; PS1987-1; PS1988-1; PS2073-1; PS2075-3; PS2076-1; PS2080-1; PS2081-1; PS2082-3; PS2087-1; PS2091-1; PS2093-1; PS2095-1; PS2096-1; PS2099-1; PS2102-1; PS2103-2; PS2104-1; PS2105-2; PS21 06AQANTX_4; PS2108-1; PS2109-3; PS22/714; PS22/717; PS22/718; PS22/720; PS22/722; PS22/727; PS22/737; PS22/744; PS22/748; PS22/764; PS22/769; PS22/797; PS22/805; PS22 06AQANTX_5; PS2230-1; PS2231-1; PS2233-1; PS2258-1; PS2259-1; PS2260-1; PS2261-1; PS2263-1; PS2265-2; PS2267-2; PS2268-6; PS2270-5; PS2275-1; PS2276-1; PS2299-1; PS2307-2; PS2491-5; PS2492-1; PS2493-3; PS2494-1; PS2495-1; PS2496-2; PS2498-2; PS2499-1; PS2500-7; PS2501-4; PS2502-3; PS2503-1; PS2504-1; PS2505-1; PS2506-1; PS2507-1; PS2508-1; PS2509-1; PS2511-1; PS2512-1; PS2513-1; PS2514-3; PS2561-1; PS2562-1; PS2563-3; PS2564-2; PS2566-1; PS2567-1; PS2600-1; PS2602-3; PS2604-4; PS2605-1; PS2606-3; PS2607-1; PS2609-2; PS2610-2; PS2611-3; PS28; PS28/264; PS28/277; PS28/280; PS28/289; PS28/293; PS28/298; PS28/304; PS28/314; PS28/316; PS28/329; PS28/334; PS28/337; PS28/339; PS28/342; PS28/345; PS28/347; PS28/350; PS28/352; PS28/361; PS28/367; PS28/373; PS28/375; PS30; PS30/030; PS30/038; PS30/043; PS30/048; PS30/055; PS30/097; PS30/137; PS30/139; PS30/141; PS30/143; PS30/144; PS30/145; PS30/147; PS30/155; PS30/156; Scotia Sea, southwest Atlantic; Shona Ridge; SL; South Atlantic; South Atlantic Ocean; South Orkney; South Sandwich; South Sandwich Basin; South Sandwich Islands; South Sandwich Trough; van Veen Grab; Vestkapp; VGRAB; Weddell Sea; Wegener Canyon
    Type: Dataset
    Format: application/zip, 4 datasets
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 10
    facet.materialart.
    Unknown
    Stable isotope record of foraminifera from South Atlantic sediments with reconstruction of paleotemperatures and paleosalinities (1995)
    PANGAEA
    In:  Supplement to: Niebler, Hans-Stefan (1995): Rekonstruktionen von Paläo-Umweltparametern anhand von stabilen Isotopen und Faunen-Vergesellschaftungen planktischer Foraminiferen im Südatlantik = Reconstruction of paleo-environmental parameters using stable isotopes and faunal assemblages of planktonic foraminifera in the South Atlantic Ocean. Berichte zur Polarforschung = Reports on Polar Research, 167, 198 pp, https://doi.org/10.2312/BzP_0167_1995
    Details
    Publication Date: 2024-07-01
    Description: Changes in surface water hydrography in the Southern Ocean (eastern Atlantic sector) could be reconstructed on the basis of isotope-geochemical and micropaleontological studies. A total of 75 high quality multicorer sediment surface samples from the southern South Atlantic Ocean and three Quaternary sediment cores, taken on a meridional transect across the Antarctic Circumpolar Current, have been investigated. The results of examining stable oxygen isotope compositions of 24 foraminiferal species and morphotypes were compared to the near-surface hydrography. The different foraminifera have been divided into four groups living at different depths in the upper water column. The 8180 differences between shallow-living (e.g. G. bulloides, N. pachyderma) and deeper-dwelling (e. g. G. inflata) species reflect the measured temperature gradient of the upper 250 m in the water column. Thus, the 6180 difference between shallow-living and deeper-living foraminifera can be used as an indicator for the vertical temperature gradient in the surface water of the Antarctic Circumpolar Current, which is independent of ice volume. All planktonic foraminifera in the surface sediment samples have been counted. 27 species and morphotypes have been selected, to form a reference data Set for statistical purposes. By using R- and Q-mode principal component analysis these planktonic foraminifera have been divided into four and five assemblages, respectively. The geographic distribution of these assemblages is mainly linked to the temperature of sea-surface waters. The five assemblages (factors) of the Q-mode principal component analysis account for 97.l % of the variance of original data. Following the transferfunction- technique a multiple regression between the Q-mode factors and the actual mean sea-surface environmental parameters resulted in a set of equations. The new transfer function can be used to estimate past sea-surface seasonal temperatures for paleoassemblages of planktonic foraminifera with a precision of approximately ±1.2°C. This transfer function F75-27-5 encompasses in particular the environmental conditions in the Atlantic sector of the Antarctic Circumpolar Current. During the last 140,000 years reconstructed sea-surface temperatures fluctuated in the present northern Subantarctic Zone (PS2076-1/3) at an amplitude of up to 7.5°C in summer and of up to 8.5°C in winter. In the present Polarfrontal Zone (PS1754-1) these fluctuations between glacials and interglacials show lower temperatures from 2.5 to 8.5°C in summer and from 1.0 to 5.0°C in winter, respectively. Compared to today, calculated oxygen isotope temperature gradients in the present Subantarctic Zone were lower during the last 140,000 years. This is an indicator for a good mixing of the upper water column. In the Polarfrontal Zone also lower oxygen isotope temperature gradients were found for the glacials 6, 4 and 2. But almost similar temperature gradients as today were found during the interglacial stages 5, 3 and the Holocene, which implicates a mixing of the upper water column compared to present. Paleosalinities were reconstructed by combining d18O-data and the evaluated transfer function paleotemperatures. Especially in the present Polarfrontal Zone (PS1754-1) and in the Antarctic Zone (PS1768-8), a short-term reduction of salinity up to 4 %o, could be detected. This significant reduction in sea-surface water salinity indicates the increased influx of melt-water at the beginning of deglaciation in the southern hemisphere at the end of the last glacial, approximately 16,500-13,000 years ago. The reconstruction of environmental Parameters indicates only small changes in the position of the frontal Systems in the eastern sector of the Antarctic Circumpolar Current during the last 140,000 years. The average position of the Subtropical Front and Subantarctic Front shifted approximately three latitudes between interglacials and glacials. The Antarctic Polar Front shifted approximately four latitudes. But substantial modifications of this scenario have been interpreted for the reconstruction of cold sea-surface temperatures at 41Â S during the oxygen isotope stages 16 and 14 to 12. During these times the Subtropical Front was probably shified up to seven latitudes northwards.
    Keywords: Agulhas Basin; ANT-IX/4; ANT-VI/3; ANT-VIII/3; ANT-X/4; ANT-X/5; ANT-X/6; Atlantic Indik Ridge; Atlantic Ridge; AWI_Paleo; Brazil Basin; Cape Basin; CTD/Rosette; CTD-RO; Discovery Seamount; GeoB1716-2; GeoB1717-2; GeoB1718-1; GeoB1719-5; GeoB1720-4; GeoB1721-4; GeoB1726-2; GeoB1728-3; GeoB1729-1; GeoB2002-2; GeoB2003-1; GeoB2004-1; GeoB2007-1; GeoB2008-1; GeoB2009-1; GeoB2016-3; GeoB2018-1; GeoB2019-2; GeoB2021-4; GeoB2022-3; Giant box corer; GKG; Gravity corer (Kiel type); KL; M20/2; M23/1; Meteor (1986); Meteor Rise; MIC; MiniCorer; MUC; MultiCorer; Namibia Continental Margin; Paleoenvironmental Reconstructions from Marine Sediments @ AWI; Piston corer (BGR type); Polarstern; PS12; PS12/557; PS16; PS16/262; PS16/267; PS16/271; PS16/278; PS16/281; PS16/284; PS16/294; PS16/303; PS16/311; PS16/312; PS16/334; PS16/337; PS16/342; PS16/345; PS16/351; PS1654-1; PS1750-7; PS1751-2; PS1752-5; PS1754-1; PS1754-2; PS1755-1; PS1756-6; PS1759-1; PS1764-2; PS1768-8; PS1769-1; PS1775-5; PS1776-6; PS1777-7; PS1778-1; PS1779-3; PS18; PS18/229; PS18/231; PS18/232; PS18/236; PS18/237; PS18/238; PS18/239; PS18/241; PS18/242; PS18/243; PS18/244; PS18/260; PS18/261; PS18/262; PS18/263; PS18/264; PS18/269; PS2073-1; PS2075-3; PS2076-1; PS2076-3; PS2080-1; PS2081-1; PS2082-3; PS2083-1; PS2084-2; PS2085-1; PS2085-2; PS2086-3; PS2087-1; PS2102-1; PS2102-2; PS2103-2; PS2104-1; PS2105-2; PS2106-1; PS21 06AQANTX_4; PS2110-1; PS22; PS22/678; PS22/755; PS22/840; PS22/841; PS22/842; PS22/850; PS22/851; PS22/852; PS22/853; PS22/879; PS22/899; PS22/902; PS22/908; PS22/947; PS22/973; PS22 06AQANTX_5; PS2230-1; PS2231-1; PS2233-1; PS2234-1; PS2235-1; PS2237-1; PS2238-1; PS2239-1; PS2240-1; PS2241-1; PS2242-1; PS2250-5; PS2250-6; PS2272-1; PS2341-1; PS2342-1; PS2343-1; PS2351-1; PS2352-1; PS2353-2; PS2354-1; PS2363-1; PS2366-1; PS2367-1; PS2368-1; PS2372-1; PS2376-1; Shona Ridge; SL; South African margin; South Atlantic; South Atlantic Ocean; Van Heesen Ridge; Walvis Ridge
    Type: Dataset
    Format: application/zip, 22 datasets
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