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Radionuclides measured on three sediment cores from the Weddell Sea, Antarctica (1995)

Frank, Martin ; Eisenhauer, Anton ; Bonn, Wolfgang J ; [et al.]

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In: Supplement to: Frank, Martin; Eisenhauer, Anton; Bonn, Wolfgang J; Walter, Peter; Grobe, Hannes; Kubik, Peter W; Dittrich-Hannen, Beate; Mangini, Augusto (1995): Sediment redistribution versus paleoproductivity change: Weddell Sea margin sediment stratigraphy and biogenic particle flux of the last 250,000 years deduced from 230Thex, 10Be and biogenic barium profiles. Earth and Planetary Science Letters, 136(3-4), 559-573, https://doi.org/10.1016/0012-821X(95)00161-5

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Publication Date: 2024-06-26

Description: High resolution 230Thex and 10Be and biogenic barium profiles were measured at three sediment gravity cores (length 605-850 cm) from the Weddell Sea continental margin. Applying the 230Thex dating method, average sedimentation rates of 3 cm/kyr for the two cores from the South Orkney Slope and of 2.4 cm/kyr for the core from the eastern Weddell Sea were determined and compared to delta18O and lithostratigraphic results. Strong variations in the radionuclide concentrations in the sediments resembling the glacial/interglacial pattern of the delta18O stratigraphy and the 10Be stratigraphy of high northern latitudes were used for establishing a chronostratigraphy. Biogenic Ba shows a pattern similar to the radionuclide profiles, suggesting that both records were influenced by increased paleoproductivity at the beginning of the interglacials. However, 230Thex0 fluxes (0 stands for initial) exceeding production by up to a factor of 4 suggest that sediment redistribution processes, linked to variations in bottom water current velocity, played the major role in controlling the radionuclide and biogenic barium deposition during isotope stages 5e and 1. The correction for sediment focusing makes the 'true' vertical paleoproductivity rates, deduced from the fluxes of proxy tracers like biogenic barium, much lower than previously estimated. Very low 230Thex0 concentrations and fluxes during isotope stage 6 were probably caused by rapid deposition of older, resedimented material, delivered to the Weddell Sea continental slopes by the grounded ice shelves and contemporaneous erosion of particles originating from the water column.

Keywords: ANT-II/3; ANT-IV/3; ANT-VI/3; Atka Bay; AWI_Paleo; Gravity corer (Kiel type); Paleoenvironmental Reconstructions from Marine Sediments @ AWI; Polarstern; PS04; PS04/257; PS08; PS08/366; PS1170-3; PS12; PS12/248; PS1388-3; PS1575-1; SL; South Atlantic Ocean; South Orkney

Type: Dataset

Format: application/zip, 6 datasets

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Sedimentation rates and geochemical analysis of surface sediments from the South Atlantic (1997)

Nürnberg, Christine Caroline ; Bohrmann, Gerhard ; Frank, Martin ; [et al.]

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In: Supplement to: Nürnberg, Christine Caroline; Bohrmann, Gerhard; Frank, Martin; Schlüter, Michael (1997): Barium accumulation in the Atlantic sector of the Southern Ocean - Results from 190,000 year records. Paleoceanography, 12(4), 594-603, https://doi.org/10.1029/97PA01130

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Publication Date: 2024-06-26

Description: Extensive investigations of sedimentary barium were performed in the southern South Atlantic in order to assess the reliability of the barium signal in Antarctic sediments as a proxy for paleoproductivity. Maximum accumulation rates of excess barium were calculated for the Antarctic zone south of the polar front where silica accumulates at high rates. The correspondence between barium and opal supports the applicability of barium as a proxy for productivity. Within the Antarctic zone north of today's average sea ice maximum, interglacial vertical rain rates of excess barium are high, with a maximum occurring during the last deglaciation and early Holocene and during oxygen isotope chronozone 5.5. During these periods, the maximum silica accumulation was supposedly located south of the polar front. Glacial paleoproductivity, instead, was low within the Antarctic zone. North of the polar front, significantly higher barium accumulation occurs during glacial times. The vertical rain rates, however, are as high as in the glacial Antarctic zone. Therefore there was no evidence for an increased productivity in the glacial Southern Ocean.

Keywords: Agulhas Basin; Agulhas Ridge; Antarctic Peninsula; ANT-IX/2; ANT-IX/3; ANT-IX/4; ANT-V/4; ANT-VI/3; ANT-VIII/3; ANT-X/4; ANT-X/5; ANT-X/6; ANT-XI/2; Atka Bay; Atlantic Indik Ridge; Atlantic Ridge; AWI_Paleo; Barents Sea; Camp Norway; Cape Basin; CTD/Rosette; CTD-RO; Eastern Weddell Sea, Southern Ocean; Falkland Islands; Filchner Trough; Giant box corer; Giant gravity corer AWI; GKG; Gravity corer (Kiel type); GSL; Halley Bay; Indian-Antarctic Ridge; Islas Orcadas; Kapp Norvegia; KL; Lazarev Sea; Lyddan Island; Maud Rise; Meteor Rise; MG; MIC; MiniCorer; MUC; Multiboxcorer; MultiCorer; Paleoenvironmental Reconstructions from Marine Sediments @ AWI; Piston corer (BGR type); Polarstern; PS10; PS10/668; PS10/672; PS10/673; PS10/675; PS10/678; PS10/684; PS10/686; PS10/690; PS10/699; PS10/701; PS10/703; PS10/707; PS10/711; PS10/719; PS10/725; PS10/738; PS10/757; PS10/762; PS10/766; PS10/778; PS10/782; PS10/784; PS10/804; PS10/816; PS10/818; PS10/820; PS10/824; PS12; PS12/242; PS12/244; PS12/247; PS12/248; PS12/250; PS12/252; PS12/271; PS12/273+276; PS12/280; PS12/284; PS12/287; PS12/289; PS12/300; PS12/302; PS12/305; PS12/310; PS12/312; PS12/319; PS12/336; PS12/338; PS12/344; PS12/348; PS12/352; PS12/364; PS12/366; PS12/374; PS12/380; PS12/382; PS12/458; PS12/486; PS12/490; PS12/492; PS12/526; PS12/534; PS12/545; PS12/551; PS12/553; PS12/555; PS12/557; PS1471-2; PS1472-4; PS1473-1; PS1474-1; PS1475-1; PS1477-1; PS1478-1; PS1480-2; PS1483-2; PS1484-2; PS1485-1; PS1486-2; PS1487-1; PS1488-1; PS1489-3; PS1490-2; PS1493-2; PS1495-1; PS1496-2; PS1498-1; PS1499-2; PS1500-2; PS1502-1; PS1506-2; PS1507-2; PS1508-2; PS1509-2; PS1572-1; PS1573-2; PS1574-1; PS1575-2; PS1576-1; PS1577-2; PS1581-2; PS1582-1; PS1584-2; PS1585-1; PS1586-2; PS1587-1; PS1590-1; PS1591-2; PS1593-1; PS1595-2; PS1596-1; PS1599-1; PS16; PS16/267; PS16/271; PS16/278; PS16/281; PS16/284; PS16/303; PS16/306; PS16/311; PS16/316; PS16/321; PS16/323; PS16/334; PS16/342; PS16/345; PS16/351; PS16/354; PS16/362; PS16/372; PS1605-3; PS1606-1; PS1609-2; PS1611-1; PS1613-2; PS1618-1; PS1619-1; PS1622-1; PS1625-1; PS1626-1; PS1635-2; PS1638-1; PS1639-1; PS1640-3; PS1645-1; PS1647-2; PS1649-1; PS1651-2; PS1652-2; PS1653-2; PS1654-1; PS1751-2; PS1752-5; PS1754-2; PS1755-1; PS1756-5; PS1756-6; PS1764-2; PS1765-1; PS1768-1; PS1768-8; PS1771-4; PS1772-6; PS1772-8; PS1773-2; PS1775-5; PS1777-7; PS1778-1; PS1779-3; PS1780-1; PS1782-6; PS1786-2; 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; PS18/084; PS18/086; PS18/088; PS18/092; PS18/094; PS18/096; PS18/100; PS18/101; PS18/102; PS18/106; PS18/108; PS18/114; PS18/118; PS18/167; PS18/186; PS18/187; PS18/196; PS18/198; PS18/199; PS18/200; PS18/201; PS18/202; PS18/203; PS18/204; PS18/218; PS18/227; PS18/229; PS18/236; PS18/237; PS18/238; PS18/241; PS18/243; PS18/244; PS18/249; PS18/250; PS18/251; PS18/252; PS18/253; PS18/254; PS18/255; PS18/256; PS18/257; PS18/261; PS18/262; PS18/263; PS18/266; PS18/267; PS18 06AQANTIX_2; PS1953-1; PS1954-1; PS1957-1; PS1958-1; PS1960-1; PS1961-1; PS1963-1; PS1964-1; PS1965-1; PS1967-1; PS1969-1; PS1970-1; PS1971-1; PS1973-1; PS1974-1; PS1975-1; PS1977-1; PS1978-1; PS1979-1; PS1981-1; PS1982-1; PS1983-1; PS1985-1; PS1986-1; PS1987-1; PS1988-1; PS2020-1; PS2039-2; PS2040-1; PS2049-3; PS2050-2; PS2051-3; PS2052-3; PS2053-1; PS2054-2; PS2055-3; PS2056-2; PS2065-1; PS2072-1; PS2073-1; PS2080-1; PS2081-1; PS2082-1; PS2084-2; PS2086-3; PS2087-1; PS2091-1; PS2092-1; PS2093-1; PS2094-1; PS2095-1; PS2096-1; PS2097-1; PS2098-1; PS2099-1; PS2103-2; PS2104-1; PS2105-2; PS21 06AQANTX_4; PS2108-1; PS2109-3; PS22; PS22/280; PS22/678; PS22/679; PS22/690; PS22/712; PS22/714; PS22/717; PS22/718; PS22/721; PS22/722; PS22/727; PS22/730; PS22/737; PS22/744; PS22/747; PS22/748; PS22/751; PS22/755; PS22/758; PS22/764; PS22/769; PS22/773; PS22/776; PS22/780; PS22/783; PS22/786; PS22/790; PS22/791; PS22/797; PS22/802; PS22/803; PS22/804; PS22/805; PS22/806; PS22/810; PS22/811; PS22/812; PS22/813; PS22/814; PS22/815; PS22/816; PS22/818; PS22/823; PS22/825; PS22/826; PS22/828; PS22/829; PS22/830; PS22/832; PS22/833; PS22/834; PS22/835; PS22/837; PS22/838; PS22/840; PS22/841; PS22/842; PS22/846; PS22/849; PS22/850; PS22/851; PS22/852; PS22/853; PS22/855; PS22/857; PS22/860; PS22/872; PS22/876; PS22/879; PS22/886; PS22/891; PS22/899; PS22/902; PS22/908; PS22/911; PS22/917; PS22/941; PS22/947; PS22/956; 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; PS2243-1; PS2244-1; PS2245-1; PS2246-1; PS2247-1; PS2248-1; PS2250-6; PS2251-1; PS2254-1; PS2256-4; PS2257-1; PS2258-1; PS2259-1; PS2260-1; PS2262-7; PS2263-1; PS2265-2; PS2266-1; PS2267-2; PS2268-6; PS2269-5; PS2270-5; PS2271-1; PS2272-1; PS2273-1; PS2275-1; PS2276-2; PS2278-5; PS2280-1; PS2283-6; PS2285-3; PS2288-1; PS2292-1; PS2293-1; PS2299-1; PS2302-2; PS2304-2; PS2305-1; PS2306-1; PS2307-2; PS2308-1; PS2312-1; PS2313-1; PS2314-1; PS2315-1; PS2316-1; PS2317-1; PS2318-1; PS2320-1; PS2325-1; PS2327-1; PS2328-1; PS2329-1; PS2330-1; PS2331-1; PS2333-1; PS2334-1; PS2335-4; PS2336-1; PS2338-1; PS2339-1; PS2341-1; PS2342-1; PS2343-1; PS2347-1; PS2350-1; PS2351-1; PS2352-1; PS2353-2; PS2354-1; PS2355-1; PS2356-1; PS2357-2; PS2361-1; PS2362-1; PS2363-1; PS2364-1; PS2365-2; PS2366-1; PS2367-1; PS2368-4; PS2369-4; PS2370-4; PS2371-1; PS2372-1; PS2374-2; PS2376-1; PS2487-2; PS2488-1; PS2489-4; PS2489-7; PS2491-5; PS2492-1; PS2493-3; PS2494-1; PS2498-2; PS2499-1; PS2501-4; PS2502-1; PS2503-1; PS2505-2; PS2506-1; PS2507-1; PS2508-1; PS2509-2; PS2511-3; PS2512-1; PS2513-1; PS2514-3; PS2515-2; PS2516-1; PS2517-5; PS2518-2; PS2519-1; PS2520-1; PS28; PS28/236; PS28/243; PS28/256; PS28/264; PS28/277; PS28/280; PS28/289; PS28/304; PS28/314; PS28/329; PS28/334; PS28/337; PS28/342; PS28/345; PS28/347; PS28/350; PS28/352; PS28/361; PS28/367; PS28/373; PS28/375; PS28/378; PS28/385; PS28/390; PS28/395; PS28/404; PS28/408; Scotia Sea, southwest Atlantic; Shona Ridge; SL; South Atlantic; South Atlantic Ocean; South Orkney; South Sandwich; South Sandwich Basin; South Sandwich Trough; van Veen Grab; Vestkapp; VGRAB; Weddell Sea; Wegener Canyon

Type: Dataset

Format: application/zip, 5 datasets

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Calcium carbonate global LGM Burial rate data (1998)

Catubig, Nina R ; Archer, David E ; Francois, Roger ; [et al.]

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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

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Publication Date: 2024-06-26

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

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Radiolarian-based bransfer function for the estimation of sea surface temperatures in the Southern Ocean (Atlantic Sector) (1999)

Abelmann, Andrea ; Brathauer, Uta ; Gersonde, Rainer ; [et al.]

PANGAEA

In: Supplement to: Abelmann, Andrea; Brathauer, Uta; Gersonde, Rainer; Sieger, Rainer; Zielinski, Ulrich (1999): Radiolarian-based transfer function for the estimation of sea surface temperatures in the Southern Ocean (Atlantic sector). Paleoceanography, 14(3), 410-421, https://doi.org/10.1029/1998PA900024

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Publication Date: 2024-06-26

Description: A new radiolarian-based transfer function for sea surface temperature (SST) estimations has been developed from 23 taxa and taxa groups in 53 surface sediment samples recovered between 35° and 72°S in the Atlantic sector of the Southern Ocean. For the selection of taxa and taxa groups ecological information from water column studies was considered. The transfer function allows the estimation of austral summer SST (December-March) ranging between -1 and 18°C with a standard error of estimate of 1.2°C. SST estimates from selected late Pleistocene squences were sucessfully compared with independend paleotemperature estimates derived from a diatom transfer function. This shows that radiolarians provide an excellent tool for paleotemperature reconstructions in Pleistocene sediments of the Southern Ocean.

Keywords: Agulhas Basin; ANT-IV/3; ANT-IV/4; ANT-IX/2; ANT-IX/4; ANT-VIII/3; ANT-VIII/6; Astrid Ridge; Atka Bay; Atlantic Ridge; AWI_Paleo; Camp Norway; Cape Basin; Filchner Shelf; Fram Strait; Giant box corer; GKG; Gravity corer (Kiel type); Indian-Antarctic Ridge; Lazarev Sea; Maud Rise; Meteor Rise; MIC; MiniCorer; MSN; MUC; MultiCorer; Multiple opening/closing net; Paleoenvironmental Reconstructions from Marine Sediments @ AWI; PLA; Plankton net; Polarstern; PS08; PS08/347; PS08/356; PS08/364; PS08/365; PS08/374; PS08/610; PS1375-2; PS1380-1; PS1386-1; PS1387-1; PS1394-1; PS1455-4; PS16; PS16/267; PS16/271; PS16/281; PS16/294; 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; PS16/507; PS16/518; PS16/534; PS16/540; PS16/547; PS16/557; PS1751-2; PS1752-5; PS1755-1; PS1759-1; PS1765-1; PS1768-1; PS1771-4; PS1772-2; PS1773-2; PS1774-1; PS1775-5; PS1776-6; PS1777-7; PS1778-1; PS1778-5; PS1779-3; PS1780-1; PS1782-6; PS1783-2; PS1786-2; PS18; PS18/055; PS18/075; PS18/084; PS18/088; PS18/092; PS18/096; PS18/229; PS18/232; PS18/236; PS18/237; PS18/238; PS18/239; PS18/241; PS18/243; PS18/244; PS18/257; PS18/260; PS18/261; PS18/262; PS18/263; PS18/267; PS1805-5; PS18 06AQANTIX_2; PS1813-3; PS1821-5; PS1823-1; PS1825-5; PS1831-5; PS1957-1; PS1967-1; PS1973-1; PS1975-1; PS1977-1; PS1979-1; PS2073-1; PS2076-1; PS2080-1; PS2081-1; PS2082-3; PS2083-2; PS2084-2; PS2086-2; PS2087-1; PS2099-1; PS2102-1; PS2103-2; PS2104-2; PS2105-2; PS2109-3; SFB261; Shona Ridge; SL; South Atlantic in Late Quaternary: Reconstruction of Budget and Currents; South Sandwich Basin; South Sandwich Islands; South Sandwich Trough; Water sample; Weddell Sea; WS

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Alkenones and coccolithophorids in late Quaternary sediments from the Walvis Ridge (1997)

Müller, Peter J ; Cepek, Martin ; Ruhland, Götz ; [et al.]

PANGAEA

In: Supplement to: Müller, Peter J; Cepek, Martin; Ruhland, Götz; Schneider, Ralph R (1997): Alkenone and coccolithophorid species changes in late Quaternary sediments from the Walvis Ridge: Implications for the alkenone paleotemperature method. Palaeogeography, Palaeoclimatology, Palaeoecology, 135(1-4), 71-96, https://doi.org/10.1016/S0031-0182(97)00018-7

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Publication Date: 2024-06-26

Description: Sea surface temperatures (SSTs) derived from the alkenone UK'37) record of Quaternary sediments may be subject to bias if algae with different temperature sensitivities have contributed to the sedimentary alkenone record. The alkenone-derived SST records are usually based on a UK'37-temperature relationship which was measured in culture experiments using the coccolithophorid Emiliania huxleyi (F.G. Prahl, L.A. Muehlhausen and D.L. Zahnle, 1988. Further evaluation of long-chain alkenones as indicators of paleoceanographic conditions. Geochim. Cosmochim. Acta 52, 2303-2310). To assess possible effects of past species changes on the UK'37-temperature signal, we have analyzed long-chain alkenones and coccolithophorids in a late Quaternary sediment core from the Walvis Ridge and compared the results to SST estimates extracted from the d18O record of the planktonic foraminifer Globigerinoides ruber. Alkenones and isotopes were determined over the entire 400-kyr core record while the coccolithophorid study was confined to the last 200 kyr when the most pronounced changes in alkenone content occurred. Throughout oxygen-isotope stages 6 and 5, species of the genus Gephyrocapsa were the predominating coccolithophorids. E. huxleyi began to increase systematically in relative abundance since the stage 5/4 transition, became dominant over Gephyrocapsa spp. during stage 3 and reached the highest abundances in the Holocene. Carbon-normalized alkenone concentrations are inversely related to the relative abundances of E. huxleyi, and directly related to that of Gephyrocapsa spp., suggesting that species of this genus were the principal alkenone contributors to the sediments. Nevertheless, SST values obtained from the UK'37-temperature relationship for E. huxleyi compare favourably to the isotope-derived temperatures. The recently reported UK'37-temperature relationship for a single strain of Gephyrocapsa oceanica (J.K. Volkman. S.M. Barrett, S.I. Blackburn and E.L. Sikes, 1995. Alkenones in Gephyrocapsa oceanica: Implications for studies of paleoclimate. Geochim. Cosmochim. Acta 59, 513-520) produces unrealistically high SST values indicating that the temperature response of the examined strain is not typical for the genus Gephyrocapsa. This is supported by the C37:C38, alkenone ratios of the sediments which are comparable to average ratios reported for E. huxleyi, but significantly higher than for the G. oceanica strain. Most notably, the general accordance of the alkenone characteristics between sediments and E. huxleyi persists through stages 8 to 5 and even in times that predate the first appearance of this species (268 ka; H.R. Thierstein, K.R. Geitzenauer and B. Molfino, 1977. Global synchroneity of late Quaternary coccolith datum levels: Validation by oxygen isotopes. Geology 5, 400-404). Our results suggest that UK'37-temperature relationships based on E. huxleyi produce reasonable paleo-SST estimates even for late Quaternary periods when this species was scarce or absent because other alkenone-synthesizing algae, e.g. of the genus Gephyrocapsa.

Keywords: GeoB; GeoB1028-5; Geosciences, University of Bremen; Gravity corer (Kiel type); M6/6; Meteor (1986); SFB261; SL; South Atlantic in Late Quaternary: Reconstruction of Budget and Currents; Walvis Ridge, Southeast Atlantic Ocean

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Recent benthic foraminifera of the Scotia Sea and Argentine Basin (1997)

Harloff, Joachim ; Mackensen, Andreas

PANGAEA

In: Supplement to: Harloff, Joachim; Mackensen, Andreas (1997): Recent benthic foraminiferal associations and ecology of the Scotia Sea and Argentine Basin. Marine Micropaleontology, 31(1-2), 1-29, https://doi.org/10.1016/S0377-8398(96)00059-X

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Publication Date: 2024-06-26

Description: We investigated 88 surface sediment samples taken with a multiple corer from the southwestern South Atlantic Ocean for their live (Rose Bengal stained) and dead benthic foraminiferal content. Using Q-Mode Principal Component Analysis six live and six dead associations are differentiated. Live and dead association distributions correspond fairly well; differences are mainly caused by downslope transport and selective test destruction. In addition, four potential fossil associations are calculated from the dead data set after removal of non-fossilizable species. These potential fossil associations are expected to be useful for paleoceanographic reconstructions. Environments are described in detail for the live and potential fossil associations and for selected species. Along the upper Argentine continental slope strong bottom currents control the occurrence of live, dead and potential fossil Angulogerina angulosa associations. Here, particles of a high organic carbon flux rate remain suspended. Below this high energy environment live, dead and potential fossil Uvigerina peregrina dominated associations correlate with enhanced sediment organic carbon content and still high organic carbon flux rates. The live A. angulosa and U. peregrina associations correlate with high standing crops. Furthermore, live and dead Epistominella exigua-Nuttallides umbonifer associations were separated. Dominance of a Nuttallides umbonifer potential fossil association relates to coverage by Antarctic Bottom Water (AABW) and Lower Circumpolar Deep Water (LCDW), above the Calcite Compensation Depth (CCD). Three associations of mainly agglutinated foraminifera occur in sediments bathed mainly by AABW or CDW. A Reophax difflugiformis association was found in mud-rich and diatomaceous sediments. Below the CCD, a Psammosphaera fusca association occurs in coarse sediments poor in organic carbon while a Cribrostomoides subglobosus-Ammobaculites agglutinans association covers a more variable environmental range with mud contents exceeding 30%. One single Eggerella bradyi-Martinottiella communis association poor in both species and individuals remains from the agglutinated associations below the CCD if only preservable species are considered for calculation.

Keywords: ANT-X/5; ANT-XI/2; AWI_Paleo; Falkland Islands; GeoB2701-4; GeoB2703-7; GeoB2704-1; GeoB2705-7; GeoB2706-6; GeoB2707-4; GeoB2708-5; GeoB2709-7; GeoB2711-2; GeoB2712-1; GeoB2714-5; GeoB2715-1; GeoB2717-8; GeoB2718-1; GeoB2719-2; GeoB2722-2; GeoB2723-2; GeoB2724-7; GeoB2725-2; GeoB2726-3; GeoB2727-1; GeoB2729-1; GeoB2730-1; GeoB2731-1; GeoB2734-2; Islas Orcadas; M29/1; Meteor (1986); MIC; MiniCorer; MUC; MultiCorer; Paleoenvironmental Reconstructions from Marine Sediments @ AWI; Polarstern; PS22/280; PS22/678; PS22/679; PS22/690; PS22/712; PS22/721; PS22/744; PS22/747; PS22/748; PS22/751; PS22/755; PS22/758; PS22/764; PS22/769; PS22/773; PS22/776; PS22/780; PS22/783; PS22/786; PS22/788; PS22/790; PS22/791; PS22/797; PS22/802; PS22/803; PS22/804; PS22/805; PS22/810; PS22/812; PS22/813; PS22/814; PS22/815; PS22/816; PS22/818; PS22/826; PS22/834; PS22 06AQANTX_5; PS2250-6; PS2251-1; PS2254-1; PS2256-4; PS2257-1; PS2262-7; PS2268-6; PS2269-5; PS2270-5; PS2271-1; PS2272-1; PS2273-2; PS2275-2; PS2276-2; PS2278-5; PS2280-1; PS2283-6; PS2285-3; PS2288-1; PS2290-1; PS2292-1; PS2293-1; PS2299-1; PS2302-2; PS2304-2; PS2305-1; PS2306-1; PS2307-2; PS2312-1; PS2314-1; PS2315-1; PS2316-1; PS2317-1; PS2318-1; PS2320-2; PS2328-1; PS2335-3; PS2498-2; PS2499-1; PS2500-7; PS2501-1; PS2503-1; PS2505-2; PS2506-1; PS2507-1; PS2508-1; PS2509-1; PS2510-1; PS2511-1; PS2513-1; PS2514-3; PS2515-2; PS2517-5; PS2518-2; PS2519-1; PS2520-1; PS28; PS28/304; PS28/314; PS28/316; PS28/329; PS28/337; PS28/342; PS28/345; PS28/347; PS28/350; PS28/352; PS28/358; PS28/361; PS28/373; PS28/375; PS28/378; PS28/390; PS28/395; PS28/404; PS28/408; Scotia Sea, southwest Atlantic; SFB261; Slope off Argentina; South Atlantic; South Atlantic in Late Quaternary: Reconstruction of Budget and Currents; South Atlantic Ocean; South Sandwich

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Iron and carbon geochemistry of sediment core GeoB1401-4 (1997)

Haese, Ralf R ; Wallmann, Klaus ; Dahmke, Andreas ; [et al.]

PANGAEA

In: Supplement to: Haese, Ralf R; Wallmann, Klaus; Dahmke, Andreas; Kretzmann, U; Müller, Peter J; Schulz, Horst D (1997): Iron species determination to investigate early diagenetic reactivity in marine sediments. Geochimica et Cosmochimica Acta, 61(1), 63-72, https://doi.org/10.1016/S0016-7037(96)00312-2

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Publication Date: 2024-06-26

Description: Iron speciation was determined in hemiplegic sediments from a high productivity area to investigate systematically the early diagenetic reactivity of Fe. A combination of various leaching agents (1 M HCI, dithionite buffered in citrate/acetic acid, HF/H2SO4, acetic Cr(II)) was applied to sediment and extracted more than 80% of total Fe. Subsequent Fe species determination defined specific mineral fractions that are available for Fe reduction and fractions formed as products of Fe diagenesis. To determine the Fe speciation of (sheet) silicates we explored an extraction procedure (HF/H2SO4) and verified the procedure by application to standard rocks. Variations of Fe speciation of (sheet) silicates reflect the possible formation of Fe-bearing silicates in near surface sediments. The same fraction indicates a change in the primary input at greater depth, which is supported by other parameters. The Fe(II)/ Fe(III) -ratio of total sediment determined by extractions was compared with Mössbauer-spectroscopy ] at room temperature and showed agreement within 10%. M6ssbauer-spectroscopy indicates the occurrence of siderite in the presence of free sulfide and pyrite, supporting the importance of microenvironments during mineral formation. The occurrence of other Fe(II) bearing minerals such as ankerite (Ca-, Fe-, Mg-carbonate) can be presumed but remains speculative.

Keywords: Congo Fan; GeoB1401-4; Gravity corer (Kiel type); M16/1; Meteor (1986); SFB261; SL; South Atlantic in Late Quaternary: Reconstruction of Budget and Currents

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Age determination of sediment cores from the Northeast Atlantic (1997)

Trauth, M H ; Sarnthein, Michael ; Arnold, Maurice

PANGAEA

In: Supplement to: Trauth, M H; Sarnthein, Michael; Arnold, Maurice (1997): Bioturbational mixing depth and carbon flux at the seafloor. Paleoceanography, 12(3), 517-526, https://doi.org/10.1029/97PA00722

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Publication Date: 2024-06-26

Description: Radiocarbon dating series, bulk sediment, and organic carbon flux from various Atlantic deep-sea regions reveal that the thickness of the bioturbated zone increases by 2 cm if food supply increases by 1 gC/m**2/yr (r = 0.8). Bulk sediment accumulation rates do not influence the depth of bioturbational mixing under normal pelagic sedimentary conditions. We believe that this relationship between nutrient supply and benthic mixing can be used for a quantitative and time-variable unmixing procedure to improve high-resolution stratigraphic correlations and paleoclimatic interpretations of deep-sea records.

Keywords: Arctic Ocean; Biscaya; Giant box corer; GIK17045-2; GIK17730-2; GIK23259-3; GKG; M11/1; M13/2; M7/2; Meteor (1986); Norwegian Sea; Quaternary Environment of the Eurasian North; QUEEN

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Sea surface temperature reconstructions of sediment cores from the Atlantic sector of the Southern Ocean (1999)

Brathauer, Uta ; Abelmann, Andrea

PANGAEA

In: Supplement to: Brathauer, Uta; Abelmann, Andrea (1999): Late Quaternary variations in sea surface temperatures and their relationship to orbital forcing recorded in the Southern Ocean (Atlantic sector). Paleoceanography, 14(2), 135-148, https://doi.org/10.1029/1998PA900020

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Publication Date: 2024-06-26

Description: Late Quaternary summer sea surface temperatures (SSTs) have been derived from radiolarian assemblages in the East Atlantic sector of the Southern Ocean. In the subantarctic and the polar frontal zone, glacial SSTs (oxygen isotope stages 2, 4, 6, and 8) were 3°-5°C cooler than today, indicating northward displacements of the isotherms about 2°-4° of latitudes. During interglacials, SSTs almost reached modern levels (oxygen isotope stages 7 and 9) or exceeded them by 2°-3°C (oxygen isotope stages 1 and 5.5). In the subantarctic Atlantic Ocean, changes in SST and calcium carbonate content of the sediment precede variations in global ice volume in the range of the main Milankovitch frequencies. Comparisons with the timing of North Atlantic Deep Water (NADW) proxy records suggests that this early response in the subantarctic Atlantic Ocean is not triggered by the flux of NADW to the Southern Ocean.

Keywords: Agulhas Basin; ANT-IX/4; ANT-VIII/3; Atlantic Ridge; AWI_Paleo; Gravity corer (Kiel type); Paleoenvironmental Reconstructions from Marine Sediments @ AWI; Polarstern; PS16; PS16/345; PS1778-5; PS18; PS18/238; PS2082-1; SFB261; SL; South Atlantic in Late Quaternary: Reconstruction of Budget and Currents

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Organic geochemistry of sediment cores from the Arbian Sea (1999)

Schulte, Sonja ; Rostek, Frauke ; Bard, Edouard ; [et al.]

PANGAEA

In: Supplement to: Schulte, Sonja; Rostek, Frauke; Bard, Edouard; Rullkötter, Jürgen; Marchal, Olivier (1999): Variations of oxygen-minimum and primary productivity recorded in sediments of the Arabian Sea. Earth and Planetary Science Letters, 173(3), 205-221, https://doi.org/10.1016/S0012-821X(99)00232-0

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Publication Date: 2024-06-26

Description: Two deep-sea sediment cores from the northeastern and the southeastern Arabian Sea were studied in order to reconstruct the palaeoenvironments of the past glacial cycles. Core 136KL was recovered from the high-productivity area off Pakistan within the modern oxygen-minimum zone (OMZ). By contrast, modern primary productivity at the site of MD900963 close to Maldives is moderate and bottom waters are today well oxygenated. For both cores, we reconstructed the changes in palaeoproductivity using a set of biomarkers (alkenones, dinosterol and brassicasterol); the main result is that primary productivity is enhanced during glacial stages and lowered during interstadials. The proxies associated with productivity show a 23 kyr cyclicity corresponding to the precession-related insolation cycle. Palaeoredox conditions were studied in both cores using a new organic geochemical parameter (C35/C31-n-alkane ratio) developed by analysing surface sediments from a transect across the OMZ off Pakistan. The value of this ratio in core 136KL shows many variations during the last 65 kyr, indicating that the OMZ was not stable during this time: it disappeared completely during Heinrich- and the Younger Dryas events, pointing to a connection between global oceanic circulation and the stability of the OMZ. The C35/C31 ratio determined in sediments of core MD900963 shows that bottom waters remained rather well oxygenated over the last 330 kyr, which is confirmed by comparison with authigenic metal concentrations in the same sediments. A zonally averaged, circulation-biogeochemical ocean model was used to explore how the intermediate Indian Ocean responds to a freshwater flux anomaly at the surface of the North Atlantic. As suggested by the geochemical time series, both the abundance of Southern Ocean Water and the oxygen concentration are significantly increased in response to this freshwater perturbation.

Keywords: Arabian Sea; GS900963; KL; Marion Dufresne (1972); MD65; MD90-963; PAKOMIN; PC; Piston corer; Piston corer (BGR type); SEYMAMA/SHIVA; SO90; SO90_136KL; Sonne

Type: Dataset

Format: application/zip, 2 datasets

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