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Presence and absence records of sea star species (class: Asteroidea) from trawl, grab and trap samples in the Weddell Sea and western Antarctic Peninsula region during POLARSTERN cruises ANT-I/2, ANT-II/4, ANT-V/3, ANT-VI/3, ANT-XV/3 and ANT-XVII/3 (2019)

Teschke, Katharina ; Brey, Thomas

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In: Alfred Wegener Institute, Helmholtz Centre for Polar and Marine Research, Bremerhaven

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Publication Date: 2023-07-10

Description: The dataset comprises a total of 7,134 records of presence and absence for 87 sea star taxa (84 % on species level, 16 % others) from 72 trawl samples (Agassiz trawl, bottom trawl, Rauschert dredge, epibenthic sledge) and 10 others (multi-box corer, giant box corer, amphipod trap, fish trap, CTD logger). The dataset was collected in the Antarctic Weddell Sea and western Antarctic Peninsula (depth range: 94 - 1353 m) during “Polarstern” cruises ANT I/2 (1983), ANT II/4 (1983/84), ANT V/3 (1987), ANT VI/3 (1987/88), ANT XV/3 (1998) and ANT XVII/3 (2000).

Keywords: Acodontaster capitatus; Acodontaster conspicuus; Acodontaster elongatus; Acodontaster hodgsoni; Acodontaster marginatus; Acodontaster sp.; Agassiz Trawl; AGT; Anteliaster australis; ANT-I/2; ANT-II/4; ANT-V/3; ANT-VI/3; ANT-XV/3; ANT-XVII/3; Area; Atka Bay; Austasen; Bathybiaster loripes; Bottom trawl; Bransfield Strait; BT; Campaign; Cheiraster (Luidiaster) gerlachei; Chitonaster johannae; Coronaster reticulatus; Cryptasterias turqueti; Cuenotaster involutus; Cycethra verrucosa mawsoni; DATE/TIME; Deception Island; DEPTH, water; Diplasterias brandti; Diplasterias brucei; Diplasterias sp.; Diplopteraster semireticulatus; Diplopteraster verrucosus; Drake Passage; Dredge, Rauschert; Drescher Inlet; EBS; Epibenthic sledge; Event label; Gear; Giant box corer; GKG; Glabraster antarctica; Halley Bay; Height; Henricia fisheri; Henricia obesa; Henricia parva; Henricia simplex; Henricia smilax; Henricia sp.; Henricia studeri; Hippasteria falklandica; Hippasteria phrygiana; Hippasteria sp.; Hymester sp.; Kampylaster incurvatus; Kampylaster sp.; Kapp Norvegia; Kenrickaster pedicellaris; King George Island, Antarctic Peninsula; Labidiaster annulatus; LATITUDE; Length; Leptychaster flexuosus; LONGITUDE; Lophaster gaini; Lophaster sp.; Lophaster stellans; Lophaster stellans marionis; Lysasterias adeliae; Lysasterias digitata; Lysasterias hemiora; Lysasterias perrieri; Lysasterias sp.; Macroptychaster accrescens; Mesh size; MG; Mirastrella biradialis; MULT; Multiboxcorer; Multiple investigations; Notasterias armata; Notasterias sp.; Notasterias stolophora; Notioceramus anomalus; Odinella nutrix; Odontaster meridionalis; Odontaster penicillatus; Odontaster validus; Paralophaster antarcticus; Paralophaster godfroyi; Paralophaster lorioli; Paralophaster sp.; Pedicellaster hypernotius; Pergamaster triseriatus; Peribolaster macleani; Perknaster antarcticus; Perknaster aurorae; Perknaster charcoti; Perknaster densus; Perknaster fuscus; Perknaster sladeni sladeni; Perknaster sp.; Polarstern; Project; PS01; PS01/135; PS01/147; PS01/149; PS01/192; PS01/194; PS01/196; PS01/216; PS01/220; PS04; PS04/308; PS04/341; PS04/372; PS04/386; PS04/438; PS04/450; PS04/474; PS04/510; PS04/521; PS04/524; PS10/537-1; PS10 WWSP86; PS12; PS12/396; PS12/396-2; PS48/039; PS48/044; PS48/049; PS48/058; PS48/062; PS48/071; PS48/077; PS48/078; PS48/079; PS48/082; PS48/088; PS48/094; PS48/095; PS48/097; PS48/100; PS48/106; PS48/120; PS48/123; PS48/150; PS48/154; PS48/167; PS48/168; PS48/189; PS48/194; PS48/197; PS48/206; PS48/220; PS48/222; PS48/263; PS48/264; PS48/277; PS48/295; PS48/303; PS48/322; PS48/336; PS48/338; PS48/353; PS48 EASIZ II; PS56/058-1; PS56/065-1; PS56/085-1; PS56/097-1; PS56/102-1; PS56/109-1; PS56/112-1; PS56/113-1; PS56/115-1; PS56/116-1; PS56/119-1; PS56/124-1; PS56/135-1; PS56/136-1; PS56/155-1; PS56/158-1; PS56/165-1; PS56/166-1; PS56/173-1; PS56/177-1; PS56/178-2; PS56/180-2; PS56/183-1; PS56/184-1; PS56/191-1; PS56 EASIZ III; Psalidaster mordax; Psalidaster sp.; Pseudarchaster discus; Psilaster charcoti; Psilaster sp.; Pteraster affinis; Pteraster gibber; Pteraster lebruni; Pteraster militarioides stoibe; Pteraster rugatus; Pteraster sp.; Pteraster stellifer; RD; Remaster gourdoni; Rhopiella hirsuta; Saliasterias brachiata; Sample ID; Ship speed; Smilasterias triremis; Solaster notophrynus; Solaster regularis; South of Vestkapp; Station label; Trap, fish; TRAPF; Trawling distance; Trawling time; Weddell Sea; Width

Type: Dataset

Format: text/tab-separated-values, 7896 data points

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Shell size, body mass and average pO2 in mantle cavity water of different marine mollusc species (2010)

Abele, Doris ; Kruppe, Melanie ; Philipp, Eva E R ; [et al.]

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In: Supplement to: Abele, Doris; Kruppe, Melanie; Philipp, Eva E R; Brey, Thomas (2010): Mantle cavity water oxygen partial pressure (Po-2) in marine molluscs aligns with lifestyle. Canadian Journal of Fisheries and Aquatic Sciences, 67(6), 977-986, https://doi.org/10.1139/F10-035

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Publication Date: 2023-12-13

Description: Marine invertebrates with open circulatory system establish low and constant oxygen partial pressure (Po2) around their tissues. We hypothesized that as a first step towards maintenance of low haemolymph and tissue oxygenation, the Po2 in molluscan mantle cavity water should be lowered against normoxic (21 kPa) seawater Po2, but balanced high enough to meet the energetic requirements in a given species. We recorded Po2 in mantle cavity water of five molluscan species with different lifestyles, two pectinids (Aequipecten opercularis, Pecten maximus), two mud clams (Arctica islandica, Mya arenaria), and a limpet (Patella vulgata). All species maintain mantle cavity water oxygenation below normoxic Po2. Average mantle cavity water Po2 correlates positively with standard metabolic rate (SMR): highest in scallops and lowest in mud clams. Scallops show typical Po2 frequency distribution, with peaks between 3 and 10 kPa, whereas mud clams and limpets maintain mantle water Po2 mostly 〈5 kPa. Only A. islandica and P. vulgata display distinguishable temporal patterns in Po2 time series. Adjustment of mantle cavity Po2 to lower than ambient levels through controlled pumping prevents high oxygen gradients between bivalve tissues and surrounding fluid, limiting oxygen flux across the body surface. The patterns of Po2 in mantle cavity water correspond to molluscan ecotypes.

Keywords: International Polar Year (2007-2008); IPY

Type: Dataset

Format: application/zip, 2 datasets

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Habitat characteristics and energy budget of the ocean quahog (Arctica islandica) (2010)

Begum, Salma ; Basova, Larisa ; Heilmayer, Olaf ; [et al.]

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In: Supplement to: Begum, Salma; Basova, Larisa; Heilmayer, Olaf; Philipp, Eva E R; Abele, Doris; Brey, Thomas (2010): Growth and energy budget models of the bivalve Arctica islandica at six different sites in the Northeast Atlantic realm. Journal of Shellfish Research, 29(1), 107-115, https://doi.org/10.2983/035.029.0103

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Publication Date: 2023-12-13

Description: We compared lifetime and population energy budgets of the extraordinary long-lived ocean quahog Arctica islandica from 6 different sites - the Norwegian coast, Kattegat, Kiel Bay, White Sea, German Bight, and off northeast Iceland - covering a temperature and salinity gradient of 4-10°C (annual mean) and 25-34, respectively. Based on von Bertalanffy growth models and size-mass relationships, we computed organic matter production of body (PSB) and of shell (PSS), whereas gonad production (PG) was estimated from the seasonal cycle in mass. Respiration (R) was computed by a model driven by body mass, temperature, and site. A. islandica populations differed distinctly in maximum life span (40 y in Kiel Bay to 197 y in Iceland), but less in growth performance (phi' ranged from 2.41 in the White Sea to 2.65 in Kattegat). Individual lifetime energy throughput, as approximated by assimilation, was highest in Iceland (43,730 kJ) and lowest in the White Sea (313 kJ). Net growth efficiency ranged between 0.251 and 0.348, whereas lifetime energy investment distinctly shifted from somatic to gonad production with increasing life span; PS/PG decreased from 0.362 (Kiel Bay, 40 y) to 0.031 (Iceland, 197 y). Population annual energy budgets were derived from individual budgets and estimates of population mortality rate (0.035/y in Iceland to 0.173/y in Kiel Bay). Relationships between budget ratios were similar on the population level, albeit with more emphasis on somatic production; PS/ PG ranged from 0.196 (Iceland) to 2.728 (White Sea), and P/B ranged from 0.203-0.285/y. Life span is the principal determinant of the relationship between budget parameters, whereas temperature affects net growth efficiency only. In the White Sea population, both growth performance and net growth efficiency of A. islandica were lowest. We presume that low temperature combined with low salinity represent a particularly stressful environment for this species.

Keywords: International Polar Year (2007-2008); IPY

Type: Dataset

Format: application/zip, 3 datasets

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Stable isotopic ratios, shell lengths and organochlorine compounds in four bivalve species collected in July 2009 around Svalbard (2012)

Vieweg, Ireen ; Hop, Haakon ; Brey, Thomas ; [et al.]

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In: Supplement to: Vieweg, Ireen; Hop, Haakon; Brey, Thomas; Huber, Sandra; Ambrose, William G Jr; Locke, William L; Gabrielsen, Geir W (2012): Persistent organic pollutants in four bivalve species from Svalbard waters. Environmental Pollution, 161, 134-142, https://doi.org/10.1016/j.envpol.2011.10.018

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Publication Date: 2023-12-13

Description: Organochlorine compounds (OC) were determined in Arctic bivalves (Mya truncata, Serripes groenlan-dicus, Hiatella arctica and Chlamys islandica) from Svalbard with regard to differences in geographic location, species and variations related to their size and age. Higher chlorinated polychlorinated biphenyls (PCB 101-PCB 194), chlordanes and alpha-hexachlorocyclohexane (alpha-HCH) were consistently detected in the bivalves and PCBs dominated the OC load in the organisms. OC concentrations were highest in Mya truncata and the lowest in Serripes groenlandicus. Species-specific OC levels were likely related to differences in the species' food source, as indicated by the d13C results, rather than size and age. Higher OC concentrations were observed in bivalves from Kongsfjorden compared to the northern sampling locations Liefdefjorden and Sjuoyane. The spatial differences might be related to different water masses influencing Kongsfjorden (Atlantic) and the northern locations (Arctic), with differing phytoplankton bloom situations.

Keywords: International Polar Year (2007-2008); IPY

Type: Dataset

Format: application/zip, 3 datasets

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