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  • 2005-2009  (2,103,514)
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  • 1
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    Standard meteorological measurements on board of POLARSTERN during expedition ANT-IV (PS08, 4 cruises, south summer 1985/86) in the Atlantic and Weddell Sea, Antarctica (2006)
    PANGAEA
    In:  Alfred Wegener Institute, Helmholtz Centre for Polar and Marine Research, Bremerhaven
    Details
    Publication Date: 2024-06-25
    Description: During the fourth Antarctic voyage ANT-IV of the research icebreaker POLARSTERN standard meteorological measurements have been performed. The measurements include 3-hourly synoptic observations as well as daily upper air soundings. The measurements started on September 6 1985 at Bremerhaven and were terminated at April 28 1986 in Punta Arenas. The 3-hourly synoptic observations are performed following the instructions of the FM 13 ships code defined by the World Meteorological Organization (WMO). The datasets include automatic measurements such as mean ship's speed, wind velocity, wind direction, air temperature, water temperature as well as visual observations such as total cloud amount, present weather, clouds, height and period of swell waves, ice classification. The visual observation are not performed during night time. For the upper air soundings VAISALA RS80 radiosondes, carried by helium-filled balloons (TOTEX 350 - 1500) were used. Data reception and evaluation were carried out by a MicroCora System (VAISALA). The upper air soundings include profile measurements of pressure, temperature, relative humidity and wind vector. Usually the soundings started at the heliport (10 m above sea level) and terminated between 15 and 37 km. The height of the measurements was calculated by applying the barometric formula. The wind vector was determined with the aid of the OMEGA navigation system.
    Keywords: ANT-IV/1a; ANT-IV/1b; ANT-IV/1c; ANT-IV/2; ANT-IV/3; ANT-IV/4; AWI_Meteo; Canarias Sea; CT; Meteorological Long-Term Observations @ AWI; North Atlantic Ocean; North Sea; Polarstern; PS08; PS08/01331; PS08/01332; PS08/01333; PS08/01334; PS08/01335; PS08/01336; PS08/01337; PS08/01338; PS08/01339; PS08/01340; PS08/01341; PS08/01342; PS08/01343; PS08/01344; PS08/01345; PS08/01346; PS08/01347; PS08/01348; PS08/01349; PS08/01350; PS08/01351; PS08/01352; PS08/01353; PS08/01354; PS08/01355; PS08/01356; PS08/01357; PS08/01358; PS08/01359; PS08/01360; PS08/01361; PS08/01362; PS08/01363; PS08/01364; PS08/01365; PS08/01366; PS08/01367; PS08/01368; PS08/01369; PS08/01370; PS08/01371; PS08/01372; PS08/01373; PS08/01374; PS08/01375; PS08/01376; PS08/01377; PS08/01378; PS08/01379; PS08/01380; PS08/01381; PS08/01382; PS08/01383; PS08/01384; PS08/01385; PS08/01386; PS08/01387; PS08/01388; PS08/01389; PS08/01390; PS08/01391; PS08/01392; PS08/01393; PS08/01394; PS08/01395; PS08/01396; PS08/01397; PS08/01398; PS08/01399; PS08/01400; PS08/01401; PS08/01402; PS08/01403; PS08/01404; PS08/01405; PS08/01414; PS08/01415; PS08/01416; PS08/01417; PS08/01418; PS08/01419; PS08/01420; PS08/01421; PS08/01422; PS08/01423; PS08/01424; PS08/01425; PS08/01426; PS08/01427; PS08/01428; PS08/01429; PS08/01430; PS08/01431; PS08/01432; PS08/01433; PS08/01434; PS08/01435; PS08/01436; PS08/01437; PS08/01438; PS08/01439; PS08/01440; PS08/01441; PS08/01442; PS08/01443; PS08/01444; PS08/01445; PS08/01446; PS08/01447; PS08/01448; PS08/01449; PS08/01450; PS08/01451; PS08/01452; PS08/01453; PS08/01454; PS08/01455; PS08/01456; PS08/01457; PS08/01458; PS08/01459; PS08/01460; PS08/01461; PS08/01462; PS08/01463; PS08/01464; PS08/01465; PS08/01466; PS08/01467; PS08/01468; PS08/01469; PS08/01470; PS08/01471; PS08/01472; PS08/01473; PS08/01474; PS08/01475; PS08/01476; PS08/01477; PS08/01478; PS08/01479; PS08/01480; PS08/01481; PS08/01482; PS08/01483; PS08/01484; PS08/01485; PS08/01486; PS08/01487; PS08/01488; PS08/01489; PS08/01490; PS08/01491; PS08/01492; PS08/01493; PS08/01494; PS08/01495; PS08/01496; PS08/01497; PS08/01498; PS08/01499; PS08/01500; PS08/01501; PS08/01502; PS08/01503; PS08/01504; PS08/01505; PS08/01506; PS08/01507; PS08/01508; PS08/01509; PS08/01510; PS08/01511; PS08/01512; PS08/01513; PS08/01514; PS08/01515; PS08/01516; PS08/01517; PS08/01518; PS08/01519; PS08/01520; PS08/01521; PS08/01522; PS08/01523; PS08/1a-track; PS08/1b-track; PS08/1c-track; PS08/2-track; PS08/3-track; PS08/4-track; PS08 NOAMP; RADIO; Radiosonde; South Atlantic Ocean; Underway cruise track measurements
    Type: Dataset
    Format: application/zip, 191 datasets
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  • 2
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    Benthic foraminiferal biodiversity response to changing Arctic palaeoclimate (2007)
    PANGAEA
    In:  Supplement to: Wollenburg, Jutta Erika; Mackensen, Andreas; Kuhnt, Wolfgang (2007): Benthic foraminiferal biodiversity response to a changing Arctic palaeoclimate in the last 24.000 years. Palaeogeography, Palaeoclimatology, Palaeoecology, 255(3-4), 195-222, https://doi.org/10.1016/j.palaeo.2007.05.007
    Details
    Publication Date: 2024-06-25
    Description: Four sediment cores recovered from 1000 to 2500 m water depth in the Arctic Ocean, tracing the inflowing Atlantic water from Fram Strait, Yermak Plateau, northern Barents Sea continental slope as far as the Laptev Sea, have been analyzed for species richness and diversity. Samples were wet sieved after freeze-drying using a 63-µm sieve. Where possible at least 300 specimens were counted from the size fraction 〉63 µm, however, samples from deglacial periods are often affected by carbonate dissolution. In such samples foraminiferal numbers are low. Samples containing less than 40 specimens were excluded from statistical analyses. Because we are aware that specimen numbers 〈100 specimen are still critical for H analyses, core sections containing less than 100 specimens are highlighted in the figures. Here, we will characterize biodiversity trends by the two most widely used biodiversity measurements, the information function H (Buzas and Gibson, 1969) with its decomposition equation ln(S) and ln(E) (Buzas and Hayek, 1996), and the Fisher Alpha Index (Fisher, Corbett, and Williams, 1943). For spectral analysis the Fisher alpha record of core PS2837-5 was resampled at equally spaced 100-year intervals. For the spectral analysis, two methodes were used within the ANALYSERIES software package (Paillard et al., 1996): 1. The Blackman-Tuckey (1958) for its high confidence of the results; 2. The maximum entropy method (e.g. Haykin, 1983) for its high resolution. The cores reveal well-correlated biodiversity maxima and minima. Distinct periodicities of species richness variability of 1.57 kyr and 0.76 kyr characterize the Late Weichselian, and of 1.16 kyr and 0.54 kyr even more pronounced the Holocene. The biodiversity maxima/minima coincide with terrestrial and marine warm and cool events at high northern latitude. We suggest that either the physiology of most rare species is temperature sensitive, or sustained food supply increased the taxonomic richness during warmer intervals.
    Keywords: ARK-III/3; ARK-IX/4; ARK-VIII/3; ARK-XIII/2; AWI_Paleo; Fram Strait; GIK21290-4 PS07/579; Gravity corer (Kiel type); KAL; Kasten corer; Laptev Sea; Paleoenvironmental Reconstructions from Marine Sediments @ AWI; Polarstern; PS07; PS1290-4; PS19/245; PS19 ARCTIC91; PS2212-3; PS2458-4; PS27; PS27/038; PS2837-5; PS44; PS44/065; SL; Yermak Plateau
    Type: Dataset
    Format: application/zip, 8 datasets
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  • 3
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    Clay minerals in the Norwegian Sea and Fram Strait, investigation from sediment traps and cores (2006)
    PANGAEA
    In:  Supplement to: Berner, Heinrich (1991): Mechanismen der Sedimentbildung in der Framstrasse, im Arktischen Ozean und in der Norwegischen See. Berichte aus dem Fachbereich Geowissenschaften der Universität Bremen, 20, 167 pp, urn:nbn:de:gbv:46-ep000106655
    Details
    Publication Date: 2024-06-25
    Description: The grain size distribution and clay mineral composition of lithogenic particles of ice-rafted material, sinking matter, surface sediments, as well as from deep-sea cores are analysed. The samples were collected in the Fram Strait, the Arctic Ocean, and the Norwegian Sea during several expeditions with the research vessels "Polarstern", "Meteor" and "Poseidon", and Norwegian rearch vessels. Sinking matter was caught with sediment traps, fitted with timer-controlled sample changers, which had been deployde in the sea for usually one year.
    Keywords: 104-1; 109-1; 111-2; 114-1; 117-1; 120-1; 121-1; 122-2; 57-04; 57-06; 57-07; 57-08; 57-09; 57-11; 57-12; 57-13; 57-14; 57-20; 58-08; Arctic Ocean; ARK-I/3; ARK-II/4; ARK-II/5; ARK-III/3; ARK-IV/3; BC; BI-1_trap; Box corer; Fram Strait; FS-1_trap; FS-2_trap; FS-3_trap; GC; GeoB; Geosciences, University of Bremen; Giant box corer; GIK16103-1; GIK16104-1; GIK16105-1; GIK16109-1; GIK16122-1; GIK16129-1; GIK16131-1; GIK16132-1; GIK16133-1; GIK16135-1; GIK16136-1; GIK16138-1; GIK16139-1; GIK16143-1; GIK16144-1; GIK16145-1; GIK16146-1; GIK16147-1; GIK16149-1; GIK16150-1; GIK16152-1; GIK16156-1; GIK16157-1; GIK16158-1; GIK16161-1; GIK16162-1; GIK16163-1; GIK16167-1; GIK16168-1; GIK16169-1; GIK16170-1; GIK16172-1; GIK16175-1; GIK16176-1; GIK16180-1; GIK21289-1 PS07/578; GIK21290-3 PS07/579; GIK21291-3 PS07/581; GIK21292-3 PS07/582; GIK21293-3 PS07/583; GIK21294-3 PS07/584; GIK21295-3 PS07/586; GIK21295-5 PS07/586; GIK21296-3 PS07/587; GIK21297-3 PS07/588; GIK21298-3 PS07/590; GIK21300-3 PS07/592; GIK21301-2 PS07/593; GIK21302-2 PS07/594; GIK21303-2 PS07/595; GIK21305-1 PS07/597; GIK21306-2 PS07/598; GIK21307-2 PS07/599; GIK21308-3 PS07/601; GIK21309-3 PS07/602; GIK21310-4 PS07/603; GIK21311-3 PS07/605; GIK21312-3 PS07/606; GIK21314-3 PS07/608; GIK21316-5 PS07/612; GIK21318-4 PS07/615; GIK21319-2 PS07/617; GIK21322-3 PS07/626; GIK21323-3 PS07/627; GIK21513-8 PS11/276-8; GIK21514-5 PS11/278-5; GIK21515-10 PS11/280-10; GIK21516-5 PS11/282-5; GIK21518-13 PS11/287-13; GIK21519-10 PS11/296-10; GIK21520-10 PS11/310-10; GIK21521-13 PS11/340-13; GIK21522-18 PS11/358-18; GIK21523-14 PS11/362-14; GIK21524-1 PS11/364-1; GIK21525-2 PS11/365-2; GIK21528-7 PS11/372-7; GIK21529-7 PS11/376-7; GIK21530-3 PS11/382-3; GIK21532-1 PS11/396-1; GIK23055-1; GIK23056-2; GIK23057-1; GIK23058-1; GIK23059-1; GIK23060-1; GIK23061-3; GIK23062-2; GIK23063-1; GIK23064-2; GIK23065-1; GIK23066-1; GIK23067-2; GIK23068-1; GIK23069-1; GIK23070-2; GIK23071-1; GIK23072-1; GIK23073-2; GIK23074-2; GIK23126-1 PS03/126; GIK23138-1 PS03/138; GIK23150-1 PS03/150; GIK23189-1 PS03/189; GIK23206-1 PS03/206; GIK23207-1 PS03/207; GIK23210-1 PS03/210; GIK23211-1 PS03/211; GIK23216-1 PS03/216; GIK23217-1 PS03/217; GIK23220-1 PS03/220; GIK23221-1 PS03/221; GIK23222-1 PS03/222; GIK23229-1 PS05/414; GIK23230-1 PS05/416; GIK23231-2 PS05/417; GIK23232-1 PS05/418; GIK23233-1 PS05/420; GIK23235-1 PS05/422; GIK23240-1 PS05/428; GIK23241-1 PS05/429; GIK23243-2 PS05/431; GIK23244-1 PS05/449; GIK23247-2 PS05/452; GIK23248-1 PS05/453; GKG; Gravity corer; Gravity corer (Kiel type); Håkon Mosby; HM52; HM52-02; HM57; HM57-04; HM57-05; HM57-06; HM57-07; HM57-08; HM57-09; HM57-11; HM57-12; HM57-13; HM57-14; HM57-20; HM58; HM58-02; HM58-08; HM82/83; ICE; Iceland Sea; Ice station; LB-1_trap; Lofoten Basin; M107-1; M118-1; M2/2; Meteor (1986); Mooring (long time); MOORY; Na-1_trap; Nansen Basin; NB-1_trap; Norway Slope; Norwegian Sea; Polarstern; PS03; PS05; PS07; PS1050-1; PS1060-1; PS1071-1; PS11; PS11/269-1; PS1105-1; PS1120-2; PS1121-1; PS1124-1; PS1125-1; PS1127-1; PS1128-1; PS1130-1; PS1131-1; PS1132-1; PS1229-1; PS1230-1; PS1231-2; PS1232-1; PS1233-1; PS1235-1; PS1240-1; PS1241-1; PS1243-2; PS1244-1; PS1247-2; PS1248-1; PS1289-1; PS1290-3; PS1291-3; PS1292-3; PS1293-3; PS1294-3; PS1295-3; PS1295-5; PS1296-3; PS1297-3; PS1298-3; PS1300-3; PS1301-2; PS1302-2; PS1303-2; PS1305-1; PS1306-2; PS1307-2; PS1308-3; PS1309-3; PS1310-4; PS1311-3; PS1312-3; PS1314-3; PS1316-5; PS1318-4; PS1319-2; PS1322-3; PS1323-3; PS1511-1; PS1513-8; PS1514-5; PS1515-10; PS1516-5; PS1518-13; PS1519-10; PS1520-10; PS1521-13; PS1522-18; PS1523-14; PS1524-1; PS1525-2; PS1528-7; PS1529-7; PS1530-3; PS1532-1; Quaternary Environment of the Eurasian North; QUEEN; Sea_Ice_A; Sea_Ice_B; Sea_Ice_C; Sea_Ice_D; SL; SP-1; SP-1_trap; Svalbard; Trap, sediment; TRAPS; Voering Plateau; Voring Plateau; VP-2_trap; Western Djupet
    Type: Dataset
    Format: application/zip, 18 datasets
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  • 4
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    Sedimentology on cores from the Greenland continental margin off Scoresby Sund (2006)
    PANGAEA
    In:  Supplement to: Stein, Ruediger; Grobe, Hannes; Hubberten, Hans-Wolfgang; Marienfeld, Peter; Nam, Seung-Il (1993): Latest Pleistocene to Holocene changes in glaciomarine sedimentation in Scoresby Sund and along the adjacent East Greenland Continental Maring: preliminary results. Geo-Marine Letters, 13, 9-16, https://doi.org/10.1007/BF01204387
    Details
    Publication Date: 2024-06-25
    Description: High-resolution stable oxygen and carbon isotope analyses and detailed sedimentological and geochemical investigations were performed in order to (i) reconstruct the paleoclimate and paleoceanography of the Greenland Sea associated with late Quaternary glacial-interglacial cycles, and (ii) to link the terrestrial and deep-sea climatic records. The reconstruction of the paleoenvironmental history of the East Greenland margin and the correlation between the terrestrial and deep sea records are major objectives of the ESF-PONAM-Programme (European Science Foundation - Polar North Atlantic Margins). For this study 16 gravity and 2 box cores were recovered along the East Greenland continental margin between 69° N and 72° N on three W-E transects running from the shelf to the deep sea.
    Keywords: ARK-V/3b; ARK-VII/3b; AWI_Paleo; GIK21726-1 PS13/193; Gravity corer (Kiel type); Greenland Sea; Greenland Shelf; Paleoenvironmental Reconstructions from Marine Sediments @ AWI; Polarstern; PS13 GRÖKORT; PS17; PS17/239; PS1726-1; PS1916-1; Quaternary Environment of the Eurasian North; QUEEN; SL
    Type: Dataset
    Format: application/zip, 4 datasets
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  • 5
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    Diatom abundance counted on water bottle samples from the EisenEx cruise to the Southern Ocean (2007)
    PANGAEA
    In:  Supplement to: Assmy, Philipp; Henjes, Joachim; Klaas, Christine; Smetacek, Victor (2007): Mechanisms determining species dominance in a phytoplankton bloom induced by the iron fertilization experiment EisenEx in the Southern Ocean. Deep Sea Research Part I: Oceanographic Research Papers, 54(3), 340-362, https://doi.org/10.1016/j.dsr.2006.12.005
    Details
    Publication Date: 2024-06-25
    Description: The dynamics of phytoplankton species populations recorded during the 3-week, iron-fertilization experiment EisenEx carried out in spring in the Antarctic Polar Frontal Zone are presented and discussed as the difference between growth and mortality rates. Only two cosmopolitan diatom species, the centric Chaetoceros debilis and the pennate Pseudo-nitzschia lineola, increased population density exponentially throughout the experiment to 150-fold and 90-fold of initial values respectively. Because C. debilis initial abundance was tenfold lower than that of P. lineola, the two contributed 1 % and 21 % to bloom biomass respectively at the end of the experiment, high-lighting the role of seeding in bloom formation. The other significant species increased population size at a linear rate throughout the experiment or for a short spurt phase to 3 to 18-fold of initial values. Conservative estimates of mortality rates within diatom species populations were obtained by comparing net accumulation rates of full cells with those of empty and broken frustules. The ratios were consistent over time for the various species but varied widely between them. The species-specific variation can be explained by differences in both growth and mortality rates, the latter partly due to either selective grazing or avoidance by the large protozoo- and metazooplankton populations present. Selective predation by the abundant copepod populations on protistan grazers (ciliates and heterotrophic dinoflagellates) of diatoms apparently aided diatom biomass build-up. The response patterns of populations of the phytoplankton species present fall into 6 categories comprising disparate species, indicating that phylogeny is a poor predictor of ecology. The group that did not respond to fertilization was the most diverse and included both endemic and cosmopolitan as well as background and bloom-forming species. This lack of response to the advent of favorable growth conditions indicates that proximate factors during EisenEx triggered growth only in some species but had little effect on others. We attribute the differences in behavior to ultimate factors such as seasonal effects on life cycles and other internal constraints on growth rates. The implications for our understanding of the evolutionary ecology of phytoplankton and its impact on global biogeochemical cycles are pointed out.
    Keywords: ANT-XVIII/2; CTD/Rosette; CTD117; CTD123; CTD126; CTD128; CTD145; CTD149; CTD16; CTD18; CTD45; CTD51; CTD54; CTD57; CTD61; CTD66; CTD70; CTD74; CTD88; CTD9; CTD-RO; EisenEx; European Iron Enrichment Experiment in the Southern Ocean; Polarstern; PS58/009-2; PS58/011-3; PS58/012-5; PS58/014-4; PS58/038-3; PS58/041-2; PS58/042-2; PS58/043-2; PS58/045-2; PS58/046-3; PS58/048-3; PS58/049-3; PS58/061-3; PS58/088-4; PS58/090-4; PS58/091-4; PS58/092-3; PS58/107-5; PS58/108-1; PS58 EISENEX; South Atlantic
    Type: Dataset
    Format: application/zip, 95 datasets
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  • 6
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    Abundance and biomass of protozooplankton from the iron-induced phytoplankton bloom during the EisenEx experiment in 2000 in the Southern Ocean (2006)
    PANGAEA
    In:  Supplement to: Henjes, Joachim; Assmy, Philipp; Klaas, Christine; Smetacek, Victor (2007): Response of the larger protozooplankton to an iron-induced phytoplankton bloom in the Polar Frontal Zone of the Southern Ocean (EisenEx). Deep Sea Research Part I: Oceanographic Research Papers, 54(5), 774-791, https://doi.org/10.1016/j.dsr.2007.02.005
    Details
    Publication Date: 2024-06-25
    Description: The responses of larger (〉50 µm in diameter) protozooplankton groups to a phytoplankton bloom induced by in situ iron fertilization (EisenEx) in the Polar Frontal Zone (PFZ) of the Southern Ocean in austral spring are presented. During the 21 days of the experiment, samples were collected from seven discrete depths in the upper 150 m inside and outside the fertilized patch for the enumeration of acantharia, foraminifera, radiolaria, heliozoa, tintinnid ciliates and aplastidic thecate dinoflagellates. Inside the patch, acantharian numbers increased twofold, but only negligibly in surrounding waters. This finding is of major interest, since acantharia are suggested to be involved in the formation of barite (BaSO_4 ) found in sediments and which is a palaeoindicator of both ancient and modern high productivity regimes. Foraminifera increased significantly in abundance inside and outside the fertilized patch. However the marked increase of juveniles after a full moon event suggests a lunar periodicity in the reproduction cycle of some foraminiferan species rather than a reproductive response to enhanced food availability. In contrast, adult radiolaria showed no clear trend during the experiment, but juveniles increased threefold indicating elevated reproduction. Aplastidic thecate dinoflagellates almost doubled in numbers and biomass, but also increased outside the patch. Tintinnid numbers decreased twofold, although biomass remained constant due to a shift in the size spectrum. Empty tintinnid loricae, however, increased by a factor of two indicating that grazing pressure on this group mainly by copepods intensified during EisenEx. The results show that iron-fertilization experiments can shed light on the biology and the role of these larger protists in pelagic ecosystem which will improve their use as proxies in palaeoceanography.
    Keywords: ANT-XVIII/2; CTD/Rosette; CTD11; CTD118; CTD121; CTD125; CTD130; CTD146; CTD15; CTD150; CTD19; CTD47; CTD52; CTD55; CTD58; CTD64; CTD67; CTD71; CTD75; CTD88; CTD-RO; EisenEx; European Iron Enrichment Experiment in the Southern Ocean; Polarstern; PS58/009-6; PS58/011-3; PS58/012-4; PS58/014-6; PS58/038-7; PS58/041-5; PS58/042-5; PS58/043-4; PS58/045-9; PS58/046-5; PS58/048-5; PS58/049-5; PS58/061-3; PS58/088-7; PS58/090-2; PS58/091-3; PS58/092-6; PS58/107-6; PS58/108-3; PS58 EISENEX; South Atlantic
    Type: Dataset
    Format: application/zip, 38 datasets
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  • 7
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    Abundance of microzooplankton determined during the EisenEx cruise ANT-XVIII/2 to the South Atlantic (2006)
    PANGAEA
    In:  Supplement to: Henjes, Joachim; Assmy, Philipp; Klaas, Christine; Verity, Peter; Smetacek, Victor (2007): Response of microzooplankton (protists and small copepods) to an iron-induced phytoplankton bloom in the Southern Ocean (EisenEx). Deep Sea Research Part I: Oceanographic Research Papers, 54(3), 363-384, https://doi.org/10.1016/j.dsr.2006.12.004
    Details
    Publication Date: 2024-06-25
    Description: The dynamics, composition and grazing impact of microzooplankton were studied during the in situ iron fertilisation experiment EisenEx in the Antarctic Polar Frontal Zone in austral spring (November 2000). During the 21 day experiment, protozooplankton and small metazooplankton were sampled from the mixed layer inside and outside the patch using Niskin bottles. Aplastidic dinoflagellates increased threefold in abundance and biomass in the first 10 d of the experiment, but decreased thereafter to values twofold higher than pre-fertilisation values. The decline after day 10 is attributed to increasing grazing pressure by copepods. They also constrained ciliate abundances and biomass which were higher inside the fertilised patch than outside but highly variable. Copepod nauplii abundance also remained stable whereas biomass doubled. Numbers of copepodites and adults of small copepod species increased threefold inside the patch, but doubled in surrounding waters. Grazing rates estimated using the dilution method suggest that microzooplankton grazing constrained pico- and nanoplankton populations, but species capable of feeding on large diatoms (dinoflagellates and small copepods including possibly nauplii) were selectively predated by the metazoan community. Thus, iron fertilisation of a developing spring phytoplankton assemblage resulted in a trophic cascade which favoured dominance of the bloom by large diatoms.
    Keywords: ANT-XVIII/2; CTD/Rosette; CTD117; CTD123; CTD126; CTD128; CTD145; CTD149; CTD16; CTD18; CTD45; CTD51; CTD54; CTD57; CTD61; CTD66; CTD70; CTD74; CTD87; CTD9; CTD-RO; EisenEx; European Iron Enrichment Experiment in the Southern Ocean; Polarstern; PS58/009-2; PS58/011-1; PS58/012-5; PS58/014-4; PS58/038-3; PS58/041-2; PS58/042-2; PS58/043-2; PS58/045-2; PS58/046-3; PS58/048-3; PS58/049-3; PS58/061-1; PS58/088-4; PS58/090-4; PS58/091-4; PS58/092-3; PS58/107-5; PS58/108-1; PS58 EISENEX; South Atlantic
    Type: Dataset
    Format: application/zip, 38 datasets
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  • 8
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    Relative abundance of dinoflagellate cysts in surface sediments and dinoflagellate counts from three sediment cores from the Atlantic sector of the Southern Ocean (2007)
    PANGAEA
    In:  Supplement to: Esper, Oliver; Zonneveld, Karin A F (2007): The potential of organic-walled dinoflagellate cysts for the reconstruction of past sea-surface conditions in the Southern Ocean. Marine Micropaleontology, 65(3-4), 185-212, https://doi.org/10.1016/j.marmicro.2007.07.002
    Details
    Publication Date: 2024-06-25
    Description: In this study we investigate the potential of organic-walled dinoflagellate cysts (dinocysts) as tools for quantifying past sea-surface temperatures (SST) in the Southern Ocean. For this purpose, a dinocyst reference dataset has been formed, based on 138 surface sediment samples from different circum-Antarctic environments. The dinocyst assemblages of these samples are composed of phototrophic (gonyaulacoid) and heterotrophic (protoperidinioid) species that provide a broad spectrum of palaeoenvironmental information. The relationship between the environmental parameters in the upper water column and the dinocyst distribution patterns of individual species has been established using the statistical method of Canonical Correspondence Analysis (CCA). Among the variables tested, summer SST appeared to correspond to the maximum variance represented in the dataset. To establish quantitative summer SST reconstructions, a Modern Analogue Technique (MAT) has been performed on data from three Late Quaternary dinocyst records recovered from locations adjacent to prominent oceanic fronts in the Atlantic sector of the Southern Ocean. These dinocyst time series exhibit periodic changes in the dinocyst assemblage during the last two glacial/interglacial-cycles. During glacial conditions the relative abundance of protoperidinioid cysts was highest, whereas interglacial conditions are characterised by generally lower cyst concentrations and increased relative abundance of gonyaulacoid cysts. The MAT palaeotemperature estimates show trends in summer SST changes following the global oxygen isotope signal and a strong correlation with past temperatures of the last 140,000 years based on other proxies. However, by comparing the dinocyst results to quantitative estimates of summer SSTs based on diatoms, radiolarians and foraminifer-derived stable isotope records it can be shown that in several core intervals the dinocyst-based summer SSTs appeared to be extremely high. In these intervals the dinocyst record seems to be highly influenced by selective degradation, leading to unusual temperature ranges and to unrealistic palaeotemperatures. We used the selective degradation index (kt-index) to determine those intervals that have been biased by selective degradation in order to correct the palaeotemperature estimates. We show that after correction the dinocyst based SSTs correspond reasonably well with other palaeotemperature estimates for this region, supporting the great potential of dinoflagellate cysts as a basis for quantitative palaeoenvironmental studies.
    Keywords: Agulhas Basin; ANT-IV/4; ANT-IX/4; ANT-VI/3; ANT-VIII/3; ANT-X/4; ANT-X/6; ANT-XVIII/5a; APSARA4; Atlantic Indik Ridge; AWI_Paleo; BC; Bounty Trough, Southwest Pacific; Box corer; Brazil Basin; Cape Basin; Central South Atlantic; ELT27; ELT27.030-PC; ELT29; ELT29.001-PC; ELT29.002-PC; ELT29.070-PC; ELT34; ELT34.006-PC; ELT34.007-PC; ELT34.009-PC; ELT34.011-PC; ELT36; ELT36.023-PC; ELT36.025-TC; ELT36.027-PC; ELT36.043-PC; ELT43; ELT43.005-PC; ELT44; ELT44.005-PC; ELT44.006-PC; ELT53; ELT53.022-PC; ELT53.023-PC; ELT53.025-PC; ELT55; ELT55.001-PC; ELT55.002-PC; ELT55.003-PC; ELT55.004-PC; ELT55.005-PC; ELT55.006-PC; ELT55.007-PC; ELT55.008-PC; ELT55.009-PC; ELT55.010-PC; Eltanin; GC; GeoB2001-1; GeoB2007-1; GeoB2008-1; GeoB2009-1; GeoB2011-1; GeoB2018-1; GeoB2019-2; GeoB2021-4; GeoB2022-3; GeoB3601-1; GeoB3602-2; GeoB3603-1; GeoB3604-4; GeoB3605-1; GeoB3809-1; GeoB3810-2; GeoB3812-2; GeoB6407-2; GeoB6409-2; GeoB6413-4; GeoB6414-1; GeoB6416-2; GeoB6417-2; GeoB6418-3; GeoB6419-2; GeoB6421-1; GeoB6422-5; GeoB6423-2; GeoB6425-1; GeoB6427-1; GeoB6429-1; Giant box corer; GKG; Gravity corer; Gravity corer (Kiel type); Indian Ocean; KAL; Kasten corer; KC029; KC032; KC046; KC064; KC073; KC075; KC078; KC081; KC083; KC084; KC090; KC095; KC098; KC100; KR88-01; KR88-02; KR88-03; KR88-04; KR88-07; KR88-08; KR88-09; KR88-13; KR88-15; KR88-16; KR88-18; KR88-25; KR88-29; KR88-30; M23/1; M34/1; M34/3; M46/4; Marion Dufresne (1972); Maud Rise; MD94-02; MD94-04; MD94-06; MD94-07; Meteor (1986); Meteor Rise; MIC; Mid Atlantic Ridge; MiniCorer; MUC; MultiCorer; Paleoenvironmental Reconstructions from Marine Sediments @ AWI; PC; Piston corer; Polarstern; PS08; PS08/621; PS12; PS12/284; PS12/549; PS12/551; PS12/557; PS1459-4; PS1585-1; PS16; PS16/284; PS16/311; PS1650-1; PS1651-2; PS1654-1; PS1756-5; PS1768-8; PS18; PS18/238; PS2082-1; PS21 06AQANTX_4; PS22; PS22/899; PS22/902; PS22/947; PS22/973; PS2230-1; PS2366-1; PS2367-1; PS2372-1; PS2376-2; PS58; PS58/251-1; PS58/254-2; PS58/256-1; PS58/258-1; PS58/265-1; PS58/266-4; PS58/267-4; PS58/268-1; PS58/269-4; PS58/270-1; PS58/272-4; PS58/274-4; PS58/276-1; PS58/280-1; PS58/290-1; PS58/291-3; PS58/292-1; Q215; Q219; Q575; Q861; R657; S924; Shona Ridge; SL; South African margin; South Atlantic; South Atlantic Ocean; Southeast Pacific; Southern Cape Basin; South Pacific; South Pacific Ocean; TAS_67GC01; TAS_67GC18; TAS_67GC44; TAS_67GC45; TAS_67GC46; TAS_67GC47; TAS_67GC49; TAS_67GC50; TAS_67GC51; TAS_67PC02; TAS_67PC03; TAS_67PC04; U938; U950
    Type: Dataset
    Format: application/zip, 4 datasets
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  • 9
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    Lithogenic and biogenic daily and annual particle fluxes on the Lomonosov Ridge of trap LOMO-2 (2007)
    PANGAEA
    In:  Supplement to: Fahl, Kirsten; Nöthig, Eva-Maria (2007): Lithogenic and biogenic particle fluxes on the Lomonosov Ridge (central Arctic Ocean) and their relevance for sediment accumulation: Vertical vs. lateral transport. Deep Sea Research Part I: Oceanographic Research Papers, 54(8), 1256-1272, https://doi.org/10.1016/j.dsr.2007.04.014
    Details
    Publication Date: 2024-06-25
    Description: Investigations of lithogenic and biogenic particle fluxes using long-term sediment traps are still very rare in the northern high latitudes and restricted to the arctic marginal seas and sub-arctic regions. Here, for the first time, data on the variability of fluxes of lithogenic matter, carbonate, opal, and organic carbon as well as biomarker composition from the central Arctic Ocean are presented for a one-year period. The study has been carried out on material obtained from a long-term mooring system equipped with two multi-sampling-traps (150 and 1550 m water depth) and deployed on the southern Lomonosov Ridge close to the Laptev Sea continental margin from September 1995 to August 1996. In addition, data from surface-sediments were included in the study to get more information about the flux and sedimentation of organic carbon in this area. Annual fluxes of lithogenic matter, carbonate, opal, and particulate organic carbon are 3.9 g/m**2/y, 0.8 g/m**2/y, 2.6 g/m**2/y, 1.5 g/m**2/y, respectively, at the shallow trap and 11.3 g/m**2/y, 0.5 g/m**2/y, 2.9 g/m**2/y, 1.05 g/m**2/y, respectively, at the deep trap. Both the shallow as well as the deep trap show significant differences in vertical flux values over the year. Higher values were found from mid-July to end of October (total flux of 75-130 mg/m**2/d in the shallow trap and 40-225 mg/m**2/d in the deep trap, respectively). During all other months, fluxes were fairly low in both traps (most total flux values 〈10 mg/m**2/d1). The interval of increased fluxes can be separated into (1) a mid-July/August maximum caused by increased primary production as documented in high abundances of marine biomarkers and diatoms, and (2) a September/October (absolute) maximum caused by increased influence of Lena river discharge indicated by maximum lithogenic flux and high portions of terrigenous/fluvial biomarkers in both traps. Here, total fluxes in the deep trap were significantly higher than in the shallow trap, suggesting a lateral sediment flux at greater depth. The lithogenic flux data also support the importance of sediment input from the Laptev Sea for the sediment accumulation on the Lomonosov Ridge on geological time scales, as indicated in sedimentary records from this region.
    Keywords: Arctic Ocean; ARK-XI/1; AWI_BioOce; AWI_Paleo; Biological Oceanography @ AWI; Mooring (long time); MOORY; Paleoenvironmental Reconstructions from Marine Sediments @ AWI; Polarstern; PS2756-1; PS36; PS36/051LOMO-2
    Type: Dataset
    Format: application/zip, 2 datasets
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  • 10
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    Abundance of copepods from multinet samples during POLARSTERN cruise ANT-XXII/2 (ISPOL) (2007)
    PANGAEA
    In:  Supplement to: Schnack-Schiel, Sigrid B; Michels, Jan; Mizdalski, Elke; Schodlok, Michael P; Schröder, Michael (2008): Composition and community structure of zooplankton in the sea ice covered western Weddell Sea in spring 2004 - with emphasis on calanoid copepods. Deep Sea Research Part II: Topical Studies in Oceanography, 55(8-9), 1040-1055, https://doi.org/10.1016/j.dsr2.2007.12.013
    Details
    Publication Date: 2024-06-25
    Description: The mesozooplankton community, with special emphasis on calanoid copepods, was studied with respect to its species composition, abundance, vertical distribution and developmental structure during the ISPOL expedition to the ice covered western Weddell Sea. Stratified zooplankton tows were carried out nine times between December 1, 2004 and January 2, 2005 with a multiple opening-closing net between 0 and 1000 m depth. Copepods were by far the most abundant taxon contributing more than 94% of the total mesozooplankton. Numerical dominants were cyclopoid copepods, mostly Oncaea spp. A total of 66 calanoid copepod species were identified, but the calanoid copepod community was characterised by the dominance of only a few species. The most numerous species was Microcalanus pygmaeus, which comprised on average 70% of all calanoids. Calanoides acutus and Metridia gerlachei represented other abundant calanoid species contributing an average of 8 and 7%, respectively. All other species comprised less than 3%. The temporal changes in the abundance and population structure of M. pygmaeus and M. gerlachei were small while a shift in the stage frequency distribution of C. acutus was observed during the study: CIV dominated the C. acutus population with 48 to 50% during the first week of December, while CV comprised 48% in late December. CI and CII of C. acutus were absent in the samples and males occurred only in very low numbers in greater depths. In M. gerlachei, CI was not found, whereas all developmental stages of M. pygmaeus occurred throughout the study. All three species showed migratory behaviour, and they occurred in upper water layers towards the end of the investigation. This vertical ascent was most pronounced in C. acutus and relatively weak in the other two species. In M. pygmaeus and M. gerlachei, copepodite stages were responsible for the upward migration in late December, while the vertical distribution of adults did not change. In C. acutus all abundant developmental stages (CIV, CV and females) ascended to upper water layers. Almost exclusively (93%) medium- and semi-ripe females of C. acutus and M. gerlachei were found, and only 3 - 4% of the ovaries were ripe. The absence of CI and the low number of ripe females indicate that the main reproductive period had not started in C. acutus and M. gerlachei until the end of our study in early January. In contrast, the high portion of CI and CII of M. pygmaeus suggests that reproduction of this species had started in October-November and hence, before the onset of the phytoplankton bloom in the water. The community structure did not differ between stations with one exception on December 26, when the station was strongly influenced by the continental shelf.
    Keywords: ANT-XXII/2; AWI_BPP; Bentho-Pelagic Processes @ AWI; MSN100; Multiple opening/closing net, 100 µm meshsize; Polarstern; PS67/006-112; PS67/006-129; PS67/006-145; PS67/006-16; PS67/006-31; PS67/006-46; PS67/006-58; PS67/006-77; PS67/006-97; PS67 ISPOL; Weddell Sea
    Type: Dataset
    Format: application/zip, 9 datasets
    Location Call Number Expected Availability
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