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Flora of Singapore precursors, 19: Nomenclatural notes on Artabotrys (Annonaceae) and Magnolia (Magnoliaceae) (2020)

Chen, J. ; Baldini, R.M.

Naturalis Biodiversity Center

In: Blumea: Biodiversity, Evolution and Biogeography of Plants vol. 65 no. 3, pp. 179-187

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Publication Date: 2024-05-25

Description: During the preparation of the accounts of Artabotrys (Annonaceae) and Magnolia (Magnoliaceae) for the Flora of Singapore, the types of all relevant names were evaluated. New lectotypes are designated for A. suaveolens and M. maingayi and a second-step lectotypification is performed for M. elegans. The citation of a lectotype locality is corrected for A. costatus and the citation of an isolectotype is improved for A. maingayi. We also clarify the previous use of the term ‘type’ to designate specimens that are in fact lectotypes for several names in Magnolia.

Keywords: Plant Science ; Ecology ; Evolution ; Behavior and Systematics ; Annonaceae ; Artabotrys ; lectotypification ; Magnoliaceae ; nomenclature ; Singapore

Repository Name: National Museum of Natural History, Netherlands

Type: info:eu-repo/semantics/article

Format: application/pdf

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Biomarker data in TOC from the (sub)Arctic (2020)

Kolling, Henriette Marie ; Stein, Ruediger ; Fahl, Kirsten ; [et al.]

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Publication Date: 2024-05-25

Keywords: 2,6,10,14-Tetramethyl-7-(3-methylpent-4-enyl)pentadecane, per unit mass total organic carbon; 24-Methylcholesta-5,22E-dien-3beta-ol, per unit mass total organic carbon; 4alpha,23,24-Trimethyl-5alpha-cholest-22E-en-3beta-ol, per unit mass total organic carbon; AMD14; AMD14_101; AMD14_115; AMD14_200; Arctic Ocean; ARK-XXIX/2.1; ARK-XXVIII/4 ALEX2014; ARK-XXXI/4; Baffin Bay; BC; Box corer; Carbon, organic, total; CCGS Amundsen; Core; CORE; CORIBAR; Davis Strait; DB3.02; DB3.08; DB3.10; DB3.11; DB3.12; DB3.13; DB3.14; DB3.15; DB3.16; DB3.20; DB3.23; DB3.24; DB3.25; DB3.26; DB3.27; DB3.30; DB3.31; DB3.32; DB3.33; DB3.34; DB3.35; DB3.36; DB3.37; DB3.39; DB3.42; DB6.01; DB6.02; DB6.05; DB6.06; DB6.07; DB6.08; DB6.09; EGS-1; Event label; FB1.02; FB1.04; FB1.05; FB1.07; FB1.12; FRAM-2014/15_ice_drift; FRAM2014/15-08-06; FRAM2014/15-11-09; FRAM2014/15-13-11; FRAM2014/15-15-13; FRAM2014/15-15-14; FRAM2014/15-15-15; FRAM2014/15-15-16; FRAM2014/15-15-17; FRAM2014/15-15-18; G. O. Sars (2003); GC; GeoB17601-2; GeoB17602-1; GeoB17603-1; GeoB17604-1; GeoB17605-1; GeoB17606-1; GeoB17607-1; GeoB17608-1; GeoB17609-1; GeoB17609-3; GeoB17610-1; GeoB17611-2; GeoB17612-1; GeoB17613-1; GeoB17614-1; GeoB17615-1; GeoB17616-1; GeoB17617-1; GeoB17618-1; GeoB17619-1; GeoB17620-1; GeoB17621-1; GeoB17622-1; GeoB17623-1; GeoB19904-1; GeoB19905-2; GeoB19916-5; GeoB19920-4; GeoB19927-2; GeoB19931-2; GeoB19933-2; GeoB19940-3; GeoB19946-3; GeoB19948-2; GeoB19953-5; GeoB19959-3; GeoB19961-2; GeoB19963-2; GeoB19969-2; GeoB19973-3; GeoB22304-4; GeoB22305-2; GeoB22306-2; GeoB22315-3; GeoB22316-1; GeoB22317-1; GeoB22318-1; GeoB22319-1; GeoB22320-1; GeoB22321-1; GeoB22329-3; GeoB22331-2; GeoB22333-3; GeoB22334-1; GeoB22336-2; GeoB22344-2; GeoB22346-2; GeoB22348-2; GeoB22350-2; GeoB22351-2; GeoB22353-2; GeoB22356-2; GeoB22357-2; GeoB22358-2; GeoB22359-2; Giant box corer; GKG; Gravity corer; Greenland Sea; GS15-198-36; GS15-198-37; GS15-198-38; GS15-198-39; GS15-198-40; GS15-198-41; GS15-198-42; GS15-198-43; GS15-198-44; GS15-198-45; GS15-198-46; GS15-198-47; GS15-198-48; GS15-198-49; GS15-198-50; GS15-198-51; GS15-198-52; GS15-198-53; GS15-198-54; GS15-198-55; GS15-198-56; GS15-198-58; GS15-198-59; GS15-198-60; GS15-198-61; GS15-198-62; GS15-198-63; GS16-204-19; GS16-204-21; GS16-204-22; GS16-204-23; GS16-204-24; GS2015-198; GS2016-204; HB2.01; HB2.02; HB2.03; HB2.04; HB2.06; Heat-Flow probe; HF; Highly branched isoprenoids, diunsatured, per unit mass total organic carbon; Highly branched isoprenoids (E), triunsatured, per unit mass total organic carbon; Highly branched isoprenoids (Z), triunsatured, per unit mass total organic carbon; HUD2008/29; HUD2008/29_14; HUD2008/29_47; HUD2008/29_55; HUD2008/29_66; HUD2013/29; HUD2013/29_51; HUD2013/29_52; HUD2013/29_54; HUD2013/29_68; HUD2013/29_78; HUD2013/29_79; Hudson; Labrador Sea; LATITUDE; LONGITUDE; Maria S. Merian; MOOR; Mooring; MSM12/2; MSM12/2_642-2; MSM12/2_643-2; MSM12/2_645-3; MSM12/2_646-2; MSM12/2_647-1; MSM12/2_649-4; MSM12/2_650-2; MSM12/2_651-2; MSM12/2_653-3; MSM12/2_654-1; MSM12/2_656-2; MSM12/2-01-02; MSM12/2-02-02; MSM12/2-03-02; MSM12/2-04-02; MSM12/2-05-01; MSM12/2-06-03; MSM12/2-07-01; MSM12/2-08-02; MSM12/2-09-02; MSM12/2-10-01; MSM12/2-12-02; MSM30; MSM30_463-2; MSM30_466-1; MSM30_467-1; MSM30_469-1; MSM30_471-1; MSM30_472-1; MSM30_474-1; MSM30_476-1; MSM30_477-1; MSM30_477-3; MSM30_479-1; MSM30_480-2; MSM30_482-1; MSM30_483-1; MSM30_485-1; MSM30_486-1; MSM30_488-1; MSM30_490-2; MSM30_493-1; MSM30_499-1; MSM30_500-1; MSM30_501-1; MSM30_502-1; MSM30_503-1; MSM31; MSM31_550-5; MSM31_557-2; MSM31_561-2; MSM31_575-3; MSM31_585-4; MSM44; MSM44_330-1; MSM44_331-2; MSM44_342-5; MSM44_346-4; MSM44_353-2; MSM44_357-2; MSM44_359-2; MSM44_366-3; MSM44_372-3; MSM44_374-2; MSM44_379-5; MSM44_385-3; MSM44_387-2; MSM44_389-2; MSM44_395-2; MSM44_399-3; MSM46; MSM46_10-8; MSM46_12-5; MSM46_14-2; MSM46_16-6; MSM46_19-3; MSM46_20-3; MSM46_22-2; MSM46_25-1; MSM46_28-3; MSM46_3-5; MSM46_4-5; MSM46_5-8; MSM46_6-4; MSM46_7-10; MSM66; MSM66/05-2; MSM66/15-3; MSM66/16-1; MSM66/17-1; MSM66/18-1; MSM66/19-1; MSM66/20-1; MSM66/21-1; MSM66/29-3; MSM66/31-2; MSM66/33-3; MSM66/34-1; MSM66/36-2; MSM66/4-4; MSM66/44-2; MSM66/46-2; MSM66/48-2; MSM66/50-2; MSM66/51-2; MSM66/53-2; MSM66/56-2; MSM66/57-2; MSM66/58-2; MSM66/59-2; MSM66/6-2; MUC; MultiCorer; Multicorer with television; North Greenland Sea; Norwegian Sea; Paamiut; Paamiut2014; Polarstern; PS109; PS109_105-1; PS109_115-2; PS109_125-1; PS109_129-1; PS109_139-1; PS109_19-2; PS109_36-2; PS109_46-2; PS109_76-1; PS109_85-1; PS109_93-2; PS115/1; PS115/1_10-1; PS115/1_17-2; PS115/1_18-1; PS115/1_19-2; PS115/1_21-1; PS115/1_22-2; PS115/1_26-1; PS115/1_4-2; PS115/1_47-1; PS115/1_48-1; PS115/1_50-1; PS115/1_51-1; PS115/1_52-2; PS115/1_6-1; PS115/1_7-1; PS115/1_9-4; PS87; PS87/029-3; PS87/030-3; PS87/035-3; PS87/040-3; PS87/067-3; PS87/068-3; PS87/070-3; PS87/074-2; PS87/076-3; PS87/079-3; PS87/086-2; PS87/099-4; PS93/011-4; PS93/016-5; PS93/017-5; PS93/018-4; PS93/020-5; PS93/023-4; PS93/024-6; PS93/030-4; PS93/031-1; PS93/039-7; PS93/041-2; PS93/046-4; PS93.1; Q7.01; Q7.03; Q7.04; Q7.07; Sabvabba; South Atlantic Ocean; Station label; TVMUC; U5.04; U5.05; U5.08; U5.09; U5.10; U5.14; U5.15; V4.01; V4.02; V4.03; V4.04

Type: Dataset

Format: text/tab-separated-values, 2046 data points

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Biomarker data in sediments from the (sub)Arctic (2020)

Kolling, Henriette Marie ; Stein, Ruediger ; Fahl, Kirsten ; [et al.]

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Publication Date: 2024-05-25

Keywords: (9E)-2,6,10,14-Tetramethyl-7-(3-methylpent-4-enyliden)pentadeca-9-ene per unit sediment mass; (9Z)-2,6,10,14-Tetramethyl-7-(3-methylpent-4-enyliden)pentadeca-9-ene per unit sediment mass; 2,10,14-Trimethyl-6-enyl-7-(3-methylpent-1-enyl)pentadecene/2,6,10,14-Tetramethyl-7-(3-methylpent-4-enyl)pentadecane ratio; 2,10,14-Trimethyl-6-enyl-7-(3-methylpent-1-enyl)pentadecene per unit sediment mass; 2,6,10,14-Tetramethyl-7-(3-methylpent-4-enyl)pentadecane per unit sediment mass; 24-Methylcholesta-5,22E-dien-3beta-ol per unit sediment mass; 4alpha,23,24-Trimethyl-5alpha-cholest-22E-en-3beta-ol per unit sediment mass; AMD14; AMD14_101; AMD14_115; AMD14_200; Arctic Ocean; ARK-XXIX/2.1; ARK-XXVIII/4 ALEX2014; ARK-XXXI/4; Baffin Bay; BC; Box corer; CCGS Amundsen; Core; CORE; CORIBAR; Davis Strait; DB3.02; DB3.08; DB3.10; DB3.11; DB3.12; DB3.13; DB3.14; DB3.15; DB3.16; DB3.20; DB3.23; DB3.24; DB3.25; DB3.26; DB3.27; DB3.30; DB3.31; DB3.32; DB3.33; DB3.34; DB3.35; DB3.36; DB3.37; DB3.39; DB3.42; DB6.01; DB6.02; DB6.05; DB6.06; DB6.07; DB6.08; DB6.09; EGS-1; Event label; FB1.02; FB1.04; FB1.05; FB1.07; FB1.12; FRAM-2014/15_ice_drift; FRAM2014/15-08-06; FRAM2014/15-11-09; FRAM2014/15-13-11; FRAM2014/15-15-13; FRAM2014/15-15-14; FRAM2014/15-15-15; FRAM2014/15-15-16; FRAM2014/15-15-17; FRAM2014/15-15-18; G. O. Sars (2003); GC; GeoB17601-2; GeoB17602-1; GeoB17603-1; GeoB17604-1; GeoB17605-1; GeoB17606-1; GeoB17607-1; GeoB17608-1; GeoB17609-1; GeoB17609-3; GeoB17610-1; GeoB17611-2; GeoB17612-1; GeoB17613-1; GeoB17614-1; GeoB17615-1; GeoB17616-1; GeoB17617-1; GeoB17618-1; GeoB17619-1; GeoB17620-1; GeoB17621-1; GeoB17622-1; GeoB17623-1; GeoB19904-1; GeoB19905-2; GeoB19916-5; GeoB19920-4; GeoB19927-2; GeoB19931-2; GeoB19933-2; GeoB19940-3; GeoB19946-3; GeoB19948-2; GeoB19953-5; GeoB19959-3; GeoB19961-2; GeoB19963-2; GeoB19969-2; GeoB19973-3; GeoB22304-4; GeoB22305-2; GeoB22306-2; GeoB22315-3; GeoB22316-1; GeoB22317-1; GeoB22318-1; GeoB22319-1; GeoB22320-1; GeoB22321-1; GeoB22329-3; GeoB22331-2; GeoB22333-3; GeoB22334-1; GeoB22336-2; GeoB22344-2; GeoB22346-2; GeoB22348-2; GeoB22350-2; GeoB22351-2; GeoB22353-2; GeoB22356-2; GeoB22357-2; GeoB22358-2; GeoB22359-2; Giant box corer; GKG; Gravity corer; Greenland Sea; GS15-198-36; GS15-198-37; GS15-198-38; GS15-198-39; GS15-198-40; GS15-198-41; GS15-198-42; GS15-198-43; GS15-198-44; GS15-198-45; GS15-198-46; GS15-198-47; GS15-198-48; GS15-198-49; GS15-198-50; GS15-198-51; GS15-198-52; GS15-198-53; GS15-198-54; GS15-198-55; GS15-198-56; GS15-198-58; GS15-198-59; GS15-198-60; GS15-198-61; GS15-198-62; GS15-198-63; GS16-204-19; GS16-204-21; GS16-204-22; GS16-204-23; GS16-204-24; GS2015-198; GS2016-204; HB2.01; HB2.02; HB2.03; HB2.04; HB2.06; Heat-Flow probe; HF; HUD2008/29; HUD2008/29_14; HUD2008/29_47; HUD2008/29_55; HUD2008/29_66; HUD2013/29; HUD2013/29_51; HUD2013/29_52; HUD2013/29_54; HUD2013/29_68; HUD2013/29_78; HUD2013/29_79; Hudson; Labrador Sea; LATITUDE; LONGITUDE; Maria S. Merian; MOOR; Mooring; MSM12/2; MSM12/2_642-2; MSM12/2_643-2; MSM12/2_645-3; MSM12/2_646-2; MSM12/2_647-1; MSM12/2_649-4; MSM12/2_650-2; MSM12/2_651-2; MSM12/2_653-3; MSM12/2_654-1; MSM12/2_656-2; MSM12/2-01-02; MSM12/2-02-02; MSM12/2-03-02; MSM12/2-04-02; MSM12/2-05-01; MSM12/2-06-03; MSM12/2-07-01; MSM12/2-08-02; MSM12/2-09-02; MSM12/2-10-01; MSM12/2-12-02; MSM30; MSM30_463-2; MSM30_466-1; MSM30_467-1; MSM30_469-1; MSM30_471-1; MSM30_472-1; MSM30_474-1; MSM30_476-1; MSM30_477-1; MSM30_477-3; MSM30_479-1; MSM30_480-2; MSM30_482-1; MSM30_483-1; MSM30_485-1; MSM30_486-1; MSM30_488-1; MSM30_490-2; MSM30_493-1; MSM30_499-1; MSM30_500-1; MSM30_501-1; MSM30_502-1; MSM30_503-1; MSM31; MSM31_550-5; MSM31_557-2; MSM31_561-2; MSM31_575-3; MSM31_585-4; MSM44; MSM44_330-1; MSM44_331-2; MSM44_342-5; MSM44_346-4; MSM44_353-2; MSM44_357-2; MSM44_359-2; MSM44_366-3; MSM44_372-3; MSM44_374-2; MSM44_379-5; MSM44_385-3; MSM44_387-2; MSM44_389-2; MSM44_395-2; MSM44_399-3; MSM46; MSM46_10-8; MSM46_12-5; MSM46_14-2; MSM46_16-6; MSM46_19-3; MSM46_20-3; MSM46_22-2; MSM46_25-1; MSM46_28-3; MSM46_3-5; MSM46_4-5; MSM46_5-8; MSM46_6-4; MSM46_7-10; MSM66; MSM66/05-2; MSM66/15-3; MSM66/16-1; MSM66/17-1; MSM66/18-1; MSM66/19-1; MSM66/20-1; MSM66/21-1; MSM66/29-3; MSM66/31-2; MSM66/33-3; MSM66/34-1; MSM66/36-2; MSM66/4-4; MSM66/44-2; MSM66/46-2; MSM66/48-2; MSM66/50-2; MSM66/51-2; MSM66/53-2; MSM66/56-2; MSM66/57-2; MSM66/58-2; MSM66/59-2; MSM66/6-2; MUC; MultiCorer; Multicorer with television; North Greenland Sea; Norwegian Sea; Paamiut; Paamiut2014; Phytoplankton biomarker Brassicasterol IP25 index; Phytoplankton biomarker C25 HBI (Z) triene IP25 index; Phytoplankton biomarker Dinosterol IP25 index; Phytoplankton biomarker HBI TR25 index; Polarstern; PS109; PS109_105-1; PS109_115-2; PS109_125-1; PS109_129-1; PS109_139-1; PS109_19-2; PS109_36-2; PS109_46-2; PS109_76-1; PS109_85-1; PS109_93-2; PS115/1; PS115/1_10-1; PS115/1_17-2; PS115/1_18-1; PS115/1_19-2; PS115/1_21-1; PS115/1_22-2; PS115/1_26-1; PS115/1_4-2; PS115/1_47-1; PS115/1_48-1; PS115/1_50-1; PS115/1_51-1; PS115/1_52-2; PS115/1_6-1; PS115/1_7-1; PS115/1_9-4; PS87; PS87/029-3; PS87/030-3; PS87/035-3; PS87/040-3; PS87/067-3; PS87/068-3; PS87/070-3; PS87/074-2; PS87/076-3; PS87/079-3; PS87/086-2; PS87/099-4; PS93/011-4; PS93/016-5; PS93/017-5; PS93/018-4; PS93/020-5; PS93/023-4; PS93/024-6; PS93/030-4; PS93/031-1; PS93/039-7; PS93/041-2; PS93/046-4; PS93.1; Q7.01; Q7.03; Q7.04; Q7.07; Sabvabba; South Atlantic Ocean; Station label; TVMUC; U5.04; U5.05; U5.08; U5.09; U5.10; U5.14; U5.15; V4.01; V4.02; V4.03; V4.04

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Environmental data from the (sub)Arctic (2020)

Kolling, Henriette Marie ; Stein, Ruediger ; Fahl, Kirsten ; [et al.]

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Publication Date: 2024-05-25

Keywords: Akademik Boris Petrov; AMD14; AMD14_101; AMD14_115; AMD14_200; ARA2B; ARA2B-11_BOX-01; ARA2B-15; ARA2B-16a_BOX-01; ARA2B-16B; ARA2B-18A; ARA2B-18B; ARA2B-1A; ARA2B-1B; ARA2B-2; ARA2B-3A; ARA2B-3B; ARA2B-8_BOX-01; ARA2B-9_BOX-01; ARA3B; ARA3B_01; ARA3B_08MUC-02; ARA3B_09MUC-02; ARA3B_10MUC-02; ARA3B_11MUC-02; ARA3B_12; ARA3B_13MUC-01; ARA3B_14MUC-01; ARA3B_15b; ARA3B_16MUC-01; ARA3B_18MUC-01; ARA3B_19MUC-02; ARA3B_26; ARA3B_27; ARA3B_28; ARA3B_29MUC-02; ARA3B_30MUC-01; ARA3B_38aMUC-01; ARA3B_41MUC-03; Araon; ARC/ASP13_Tyro-5; ARC/ASP13_YS163; ARC/ASP14_Tyro-8; ARC/ASP14_YS3.14; ARC/IGN15_SD60; ARC/IGN15_Tyro-100; ARC/IGN15_YS3.18; ARC/IGN15_YSD; ARC/IGN15_Z60; ARC-1; ARC-2; ARC-3; ARC-4; ARC-5; ARC-6; ARC-7; ARC-8; ArcticNet2005; ArcticNet2005_ARC-1; ArcticNet2005_ARC-2; ArcticNet2005_ARC-3; ArcticNet2005_ARC-4; ArcticNet2005_ARC-5; ArcticNet2005_ARC-6; ArcticNet2005_ARC-7; ArcticNet2005_ARC-8; Arctic Ocean; ARK-VIII/2; ARK-X/2; ARK-XI/1; ARK-XIV/1a; ARK-XIX/4a; ARK-XV/2; ARK-XVI/1; ARK-XVI/2; ARK-XVII/1; ARK-XVII/2; ARK-XVIII/1; ARK-XXIX/2.1; ARK-XXVI/3; ARK-XXVII/3; ARK-XXVIII/4 ALEX2014; ARK-XXXI/4; Baffin Bay; Barents_625; Barents_627; Barents_629; Barents_631; Barents_633; Barents_635; Barents_639; Barents_643; Barents_645; Barents_647; Barents_649; Barents_651; Barents_653; Barents_655; Barents_657; Barents_659; Barents_661; Barents_663; Barents_665; Barents_667; Barents_669; Barents_671; Barents_673; Barents_675; Barents_677; Barents_679; Barents_681; Barents_690; Barents_692; Barents_St02; Barents_St03; Barents_St04; Barents_St06; Barents_St07; Barents_St09; Barents_St11; Barents_St12; Barents_St13; Barents_St14; Barents_St15; Barents_St17; Barents_St18; Barents_St19; Barents_St20; Barents_St21; Barents_St22; Barents_St23; Barents_St24; Barents_St25; Barents_St26; Barents_St27; Barents_St29; Barents_St30; Barents_St31; Barents_St32; Barents_St34; Barents_St35; Barents_St36; Barents_St37; Barents_St38; Barents_St39; Barents_St40; Barents_St41; Barents_St43; Barents_St44; Barents_St45; Barents Sea; BC; Bering Sea; Box corer; BP00; BP00-02; BP00-04; BP00-05; BP00-07; BP00-08; BP00-09; BP00-13; BP00-14; BP00-15; BP00-16; BP00-17; BP00-22; BP00-23; BP00-26; BP00-27; BP00-28; BP00-29; BP00-30; BP00-31; BP00-35; BP00-36; BP00-38; BP01; BP01-38; BP01-43; BP01-64; BP01-67; BP01-73a; BP01-74; BP01-75; BP01-76; BP01-78; BP01-79; BP02; BP02-01B; BP02-02B; BP02-03/01; BP02-05/01; BUCKET; Bucket water sampling; CCGS Amundsen; Core; CORE; CORIBAR; CTD/Rosette; CTD-RO; Davis Strait; DB3.02; DB3.08; DB3.10; DB3.11; DB3.12; DB3.13; DB3.14; DB3.15; DB3.16; DB3.20; DB3.23; DB3.24; DB3.25; DB3.26; DB3.27; DB3.30; DB3.31; DB3.32; DB3.33; DB3.34; DB3.35; DB3.36; DB3.37; DB3.39; DB3.42; DB6.01; DB6.02; DB6.05; DB6.06; DB6.07; DB6.08; DB6.09; DEPTH, water; Dredge; DRG; East Greenland Sea; East Siberian Sea; EGS-1; Event label; FB1.02; FB1.04; FB1.05; FB1.07; FB1.12; FRAM-2014/15_ice_drift; FRAM2014/15-08-06; FRAM2014/15-11-09; FRAM2014/15-13-11; FRAM2014/15-15-13; FRAM2014/15-15-14; FRAM2014/15-15-15; FRAM2014/15-15-16; FRAM2014/15-15-17; FRAM2014/15-15-18; G. O. Sars (2003); GC; GeoB17601-2; GeoB17602-1; GeoB17603-1; GeoB17604-1; GeoB17605-1; GeoB17606-1; GeoB17607-1; GeoB17608-1; GeoB17609-1; GeoB17609-3; GeoB17610-1; GeoB17611-2; GeoB17612-1; GeoB17613-1; GeoB17614-1; GeoB17615-1; GeoB17616-1; GeoB17617-1; GeoB17618-1; GeoB17619-1; GeoB17620-1; GeoB17621-1; GeoB17622-1; GeoB17623-1; GeoB19904-1; GeoB19905-2; GeoB19916-5; GeoB19920-4; GeoB19927-2; GeoB19931-2; GeoB19933-2; GeoB19940-3; GeoB19946-3; GeoB19948-2; GeoB19953-5; GeoB19959-3; GeoB19961-2; GeoB19963-2; GeoB19969-2; GeoB19973-3; GeoB22304-4; GeoB22305-2; GeoB22306-2; GeoB22315-3; GeoB22316-1; GeoB22317-1; GeoB22318-1; GeoB22319-1; GeoB22320-1; GeoB22321-1; GeoB22329-3; GeoB22331-2; GeoB22333-3; GeoB22334-1; GeoB22336-2; GeoB22344-2; GeoB22346-2; GeoB22348-2; GeoB22350-2; GeoB22351-2; GeoB22353-2; GeoB22356-2; GeoB22357-2; GeoB22358-2; GeoB22359-2; Giant box corer; GKG; Gravity corer; Gravity corer (Kiel type); Greenland Sea; GS15-198-36; GS15-198-37; GS15-198-38; GS15-198-39; GS15-198-40; GS15-198-41; GS15-198-42; GS15-198-43; GS15-198-44; GS15-198-45; GS15-198-46; GS15-198-47; GS15-198-48; GS15-198-49; GS15-198-50; GS15-198-51; GS15-198-52; GS15-198-53; GS15-198-54; GS15-198-55; GS15-198-56; GS15-198-58; GS15-198-59; GS15-198-60; GS15-198-61; GS15-198-62; GS15-198-63; GS16-204-19; GS16-204-21; GS16-204-22; GS16-204-23; GS16-204-24; GS2015-198; GS2016-204; HB2.01; HB2.02; HB2.03; HB2.04; HB2.06; HE153; HE153/1239-2; HE153/1241-1; HE153/1251-2; HE153/1254-2; HE153/1255-2; HE153/1261-2; HE153/1262-2; HE153/1263-2; HE153/1265-2; HE153/1269-2; HE153/1270-2; HE153/1273-2; HE153/1286-2; HE153/1287-2; HE153/1288-2; HE153/1289-2; HE153/1290-2; Heincke; Helmer Hanssen; HG_I; HG_II; HG_IV; HG_IX; HH11; HH11-133GC; HH11-134BC; HH11-135GC; HH11-136BC; HH11-137BC; HH11-138GC; HH11-140BC; HH13-19; HH13-21; HH13-23E; HH13-25F; HH2011; HH2013; HUD2008/29; HUD2008/29_14; HUD2008/29_47; HUD2008/29_55; HUD2008/29_66; HUD2013/29; HUD2013/29_51; HUD2013/29_52; HUD2013/29_54; HUD2013/29_68; HUD2013/29_78; HUD2013/29_79; Hudson; Hudson Bay; Hurry Inlet, East Greenland; Iceland Sea; INOPEX; Investigator; James Clark Ross; JR142; JR142-GC10; JR142-GC11; JR142-GC12; JR142-GC13; JR142-GC14; JR142-GC15; JR142-GC17; JR142-GC19; JR142-GC20; JR142-GC21; JR142-GC22; JR142-GC23; JR142-GC4; JR142-GC5; JR142-GC6; JR142-GC7; JR142-GC8; JR142-GC9; JR20060728; JR20080823; JR211; JR211-04GC; JR211-10BC; JR211-12GC; JR211-13GC; JR211-15GC; JR211-26GC; JR211-28GC; JR211-33GC; KAL; Kapitan Dranitsyn; Kara Sea; Kasten corer; KD9523-8; KD9529-12; KD9533-11; KD9541-13; KD9548-13; KD9565-12; KD9568-8; KD9572-1; Kempe Fjord, East Greenland; Labrador Sea; Laptev Sea; LATITUDE; LONGITUDE; Maria S. Merian; MOOR; Mooring; MSM12/2; MSM12/2_642-2; MSM12/2_643-2; MSM12/2_645-3; MSM12/2_646-2; MSM12/2_647-1; MSM12/2_649-4; MSM12/2_650-2; MSM12/2_651-2; MSM12/2_653-3; MSM12/2_654-1; MSM12/2_656-2; MSM12/2-01-02; MSM12/2-02-02; MSM12/2-03-02; MSM12/2-04-02; MSM12/2-05-01; MSM12/2-06-03; MSM12/2-07-01; MSM12/2-08-02; MSM12/2-09-02; MSM12/2-10-01; MSM12/2-12-02; MSM30; MSM30_463-2; MSM30_466-1; MSM30_467-1; MSM30_469-1; MSM30_471-1; MSM30_472-1; MSM30_474-1; MSM30_476-1; MSM30_477-1; MSM30_477-3; MSM30_479-1; MSM30_480-2; MSM30_482-1; MSM30_483-1; MSM30_485-1; MSM30_486-1; MSM30_488-1; MSM30_490-2; MSM30_493-1; MSM30_499-1; MSM30_500-1; MSM30_501-1; MSM30_502-1; MSM30_503-1; MSM31; MSM31_550-5; MSM31_557-2; MSM31_561-2; MSM31_575-3; MSM31_585-4; MSM44; MSM44_330-1; MSM44_331-2; MSM44_342-5; MSM44_346-4; MSM44_353-2; MSM44_357-2; MSM44_359-2; MSM44_366-3; MSM44_372-3; MSM44_374-2; MSM44_379-5; MSM44_385-3; MSM44_387-2; MSM44_389-2; MSM44_395-2; MSM44_399-3; MSM46; MSM46_10-8; MSM46_12-5; MSM46_14-2; MSM46_16-6; MSM46_19-3; MSM46_20-3; MSM46_22-2; MSM46_25-1; MSM46_28-3; MSM46_3-5; MSM46_4-5; MSM46_5-8; MSM46_6-4; MSM46_7-10; MSM66; MSM66/05-2; MSM66/15-3; MSM66/16-1; MSM66/17-1; MSM66/18-1; MSM66/19-1; MSM66/20-1; MSM66/21-1; MSM66/29-3; MSM66/31-2; MSM66/33-3; MSM66/34-1; MSM66/36-2; MSM66/4-4; MSM66/44-2; MSM66/46-2; MSM66/48-2; MSM66/50-2; MSM66/51-2; MSM66/53-2; MSM66/56-2; MSM66/57-2; MSM66/58-2; MSM66/59-2; MSM66/6-2; MSN; MUC; MULT; MultiCorer; Multicorer with television; Multiple investigations; Multiple opening/closing net; Nitrate; North Greenland Sea; North Pacific Ocean; Northwestern Passages; Norwegian Sea; NOW-1; NOW-2; NOW-3; NOW-4; NOW-5; Number; OBS; OBS314; Ocean bottom seismometer; Paamiut; Paamiut2014; Phosphate; Polarstern; Primary production of carbon; PS109; PS109_105-1; PS109_115-2; PS109_125-1; PS109_129-1; PS109_139-1; PS109_19-2; PS109_36-2; PS109_46-2; PS109_76-1; PS109_85-1; PS109_93-2; PS19/040; PS19/045; PS19/078; PS19/080; PS19/082; PS19/102; PS19/116; PS19/119; PS19/126; PS19/132; PS19/134; PS19/136; PS19/143; PS19 EPOS II; PS2111-2; PS2113-1; PS2117-1; PS2119-2; PS2121-1; PS2131-1; PS2142-3; PS2144-3; PS2148-1; PS2149-1; PS2150-

Type: Dataset

Format: text/tab-separated-values, 15755 data points

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Influence of late Quaternary climate on the biogeography of Neotropical aquatic species as reflected by non-marine ostracodes (2020)

Cohuo, Sergio ; Macario-González, Laura ; Wagner, Sebastian ; [et al.]

Copernicus Publications EU

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Publication Date: 2024-05-24

Description: We evaluated how ranges of four endemic and non-endemic aquatic ostracode species changed in response to long-term (glacial–interglacial cycles) and abrupt climate fluctuations during the last 155 kyr in the northern Neotropical region. We employed two complementary approaches, fossil records and species distribution models (SDMs). Fossil assemblages were obtained from sediment cores PI-1, PI-2, PI-6 and Petén-Itzá 22-VIII-99 from the Petén Itzá Scientific Drilling Project, Lake Petén Itzá, Guatemala. To obtain a spatially resolved pattern of (past) species distribution, a downscaling cascade is employed. SDMs were reconstructed for the last interglacial (∼120 ka), the last glacial maximum (∼22 ka) and the middle Holocene (∼6 ka). During glacial and interglacial cycles and marine isotope stages (MISs), modelled paleo-distributions and paleo-records show the nearly continuous presence of endemic and non-endemic species in the region, suggesting negligible effects of long-term climate variations on aquatic niche stability. During periods of abrupt ecological disruption such as Heinrich Stadial 1 (HS1), endemic species were resilient, remaining within their current areas of distribution. Non-endemic species, however, proved to be more sensitive. Modelled paleo-distributions suggest that the geographic range of non-endemic species changed, moving southward into Central America. Due to the uncertainties involved in the downscaling from the global numerical to the highly resolved regional geospatial statistical modelling, results can be seen as a benchmark for future studies using similar approaches. Given relatively moderate temperature decreases in Lake Petén Itzá waters (∼5 ∘C) and the persistence of some aquatic ecosystems even during periods of severe drying in HS1, our data suggest (1) the existence of micro-refugia and/or (2) continuous interaction between central metapopulations and surrounding populations, enabling aquatic taxa to survive climate fluctuations in the northern Neotropical region.

Type: Article , PeerReviewed

Format: text

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Impacts of combined temperature and salinity stress on the endemic Arctic brown seaweed Laminaria solidungula – physiological and biochemical results of laboratory experiments with young sporophytes (2020)

Diehl, Nora ; Karsten, Ulf ; Bischof, Kai

PANGAEA

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Publication Date: 2024-05-24

Description: Macroalgae such as kelp are important ecosystem engineers in the Polar Regions and potentially affected by freshening and ocean warming. The endemic Arctic kelp Laminaria solidungula might be particularly imperiled and become locally extinct from Arctic fjord systems in the future, since temperature increase is most pronounced in the Polar Regions. Additionally, increased temperatures cause glacier and sea ice melting and enhancing terrestrial run-off from snowfields, which eventually can result in hyposaline conditions in fjord systems. We conducted a multiple-stressor experiment at four temperatures (0, 5, 10, 15 °C) and two salinities (SA 25, 35) over 14 days to investigate the combined effects of increasing temperature and decreasing salinities on young L. solidungula sporophytes. The experiment was conducted with laboratory cultures (AWI culture number 3130) at Alfred Wegener Institute - Helmholtz Centre for Polar and Marine Research, Bremerhaven in February 2018. As physiological parameter, the maximum photosynthetic quantum yield of photosystem II (Fv/Fm; Imaging-PAM) was monitored every fourth day with an Imaging-PAM (Walz GmbH Mess- und Regeltechnik, Effeltrich, Germany). The total nitrogen, total carbon content was analyzed with an elemental analyzer and the C:N ratio calculated. Phlorotannins, mannitol as well as absolute pigment concentrations were analyzed using a HPLC and the deepoxydation state of the xanthophyll cycle (DPS) calculated.

Keywords: beta-Carotene; C:N; Carbon, per dry mass; Carbon/Nitrogen ratio; Chlorophyll a; Chlorophyll c2; De-expoxidation state of xanthophyll cycle; DPS; Family; Fucoxanthin; Fv/Fm; High Performance Liquid Chromatography (HPLC); Imaging-PAM (Walz GmbH Mess- und Regeltechnik, Effeltrich, Germany); kelp; Mannitol; Maximum quantum yield of photosystem II; Multiple-stressor; Nitrogen, per dry mass; Phlorotannins; Replicate; Species; Treatment: salinity; Treatment: temperature; Violaxanthin + Antheraxanthin + Zeaxanthin

Type: Dataset

Format: text/tab-separated-values, 2212 data points

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Antarctic ascidians respiration rate under increasing sedimentation (2020)

Torre, Luciana ; Tatián, Marcos ; Momo, Fernando ; [et al.]

PANGAEA

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Publication Date: 2024-05-24

Description: The file includes the respiration rate (milligrams of Oxygen per gram of dry mass (without tunic) per day) of three antarctic solitary ascidians (Cnemidocarpa verrucosa, Molgula pedunculata and Ascidia challengeri) under increasing sediment concentrations (from natural seston (NS) to NS + Additional Suspended particulate matter (SPM) from 5 to 400 mg/L). Individuals were sampled carefully by SCUBA diving during austral summer 2006-2007 in Potter Cove (58°43'5.214"W; 62°14'24.184"S) at 20 m depth. Experiments where performed after acclimation to aquarium conditions in the Dallmann laboratory on Carlini station (58°43'5.214"W; 62°14'24.184"S).

Keywords: Antarctica; ascidians; DIVER; Experimental treatment; invertebrates; Metabolic rate of oxygen, per dry mass; metabolism; PotterCove_SCUBA_06-07; Potter Cove, King George Island, Antarctic Peninsula; Respiration rate; Sampling by diver; sedimentation; Species; Specimen identification

Type: Dataset

Format: text/tab-separated-values, 770 data points

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Basic and other measurements of radiation at station Gobabeb (2019-11) (2020)

Vogt, Roland

PANGAEA

In: Meteorology Climatology Remote Sensing, Dep. Umweltwissenschaften, Universität Basel

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Publication Date: 2024-05-24

Description: In Gobabeb, Namibia SWD, LWD and DIR are each measured redundant with two instruments of the same make (not in this data base). The differences between the pairs are used in the quality control. This is done manually by inspecting plots of half-day diurnal courses of the pairs and their differences. Values are removed mostly in the morning due to daily cleaning. Other reasons for larger differences are birds, insects, or people at the station. There are regular fog events varying in frequency over the year. Usually, the fog appears in the second half of the night and disappears a few hours after sunrise. The case temperatures of pyrgeometers practically never drop below dewpoint but there can be water deposition of the dome.

Keywords: Air temperature at 2 m height; BARO; Barometer; Baseline Surface Radiation Network; BSRN; DATE/TIME; Diffuse radiation; Diffuse radiation, standard deviation; Direct radiation; Direct radiation, standard deviation; GOB; Gobabeb; HEIGHT above ground; Humidity, relative; HYGRO; Hygrometer; Long-wave downward radiation; Long-wave downward radiation, standard deviation; Long-wave upward radiation; Monitoring station; MONS; Namib Desert, Namibia; Pyranometer, Kipp & Zonen, CMP22, SN 110315, WRMC No. 20100; Pyranometer, Kipp & Zonen, CMP22, SN 110316, WRMC No. 20101; Pyranometer, Kipp & Zonen, CMP22, SN 120330, WRMC No. 20102; Pyrgeometer, Kipp & Zonen, CGR4, SN 110408, WRMC No. 20200; Pyrgeometer, Kipp & Zonen, CGR4, SN 120457, WRMC No. 20201; Pyrheliometer, Kipp & Zonen, CHP 1, SN 110764, WRMC No. 20000; Short-wave downward (GLOBAL) radiation; Short-wave downward (GLOBAL) radiation, standard deviation; Short-wave upward (REFLEX) radiation; Station pressure; Thermometer

Type: Dataset

Format: text/tab-separated-values, 561508 data points

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Basic and other measurements of radiation at station Gobabeb (2020-01) (2020)

Vogt, Roland

PANGAEA

In: Meteorology Climatology Remote Sensing, Dep. Umweltwissenschaften, Universität Basel

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Publication Date: 2024-05-24

Description: In Gobabeb, Namibia SWD, LWD and DIR are each measured redundant with two instruments of the same make (not in this data base). The differences between the pairs are used in the quality control. This is done manually by inspecting plots of half-day diurnal courses of the pairs and their differences. Values are removed mostly in the morning due to daily cleaning. Other reasons for larger differences are birds, insects, or people at the station. There are regular fog events varying in frequency over the year. Usually, the fog appears in the second half of the night and disappears a few hours after sunrise. The case temperatures of pyrgeometers practically never drop below dewpoint but there can be water deposition of the dome.

Keywords: Air temperature at 2 m height; BARO; Barometer; Baseline Surface Radiation Network; BSRN; DATE/TIME; Diffuse radiation; Diffuse radiation, standard deviation; Direct radiation; Direct radiation, standard deviation; GOB; Gobabeb; HEIGHT above ground; Humidity, relative; HYGRO; Hygrometer; Long-wave downward radiation; Long-wave downward radiation, standard deviation; Long-wave upward radiation; Monitoring station; MONS; Namib Desert, Namibia; Pyranometer, Kipp & Zonen, CMP22, SN 110315, WRMC No. 20100; Pyranometer, Kipp & Zonen, CMP22, SN 110316, WRMC No. 20101; Pyranometer, Kipp & Zonen, CMP22, SN 120330, WRMC No. 20102; Pyrgeometer, Kipp & Zonen, CGR4, SN 110408, WRMC No. 20200; Pyrgeometer, Kipp & Zonen, CGR4, SN 120457, WRMC No. 20201; Pyrheliometer, Kipp & Zonen, CHP 1, SN 110764, WRMC No. 20000; Short-wave downward (GLOBAL) radiation; Short-wave downward (GLOBAL) radiation, standard deviation; Short-wave upward (REFLEX) radiation; Station pressure; Thermometer

Type: Dataset

Format: text/tab-separated-values, 580143 data points

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Experiment on pH effects on coralline-epiphyte complex (Ellisolandia elongata): metabolic response (2020)

Guy-Haim, Tamar

PANGAEA

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Publication Date: 2024-05-24

Keywords: Biomass, ash free dry mass; Biomass, ash free dry mass, standard deviation; calcification; Calcification rate, standard deviation; Climate change; coralline algae; diffusive boundary layer; epiphytism; microenvironment; Net calcification rate of calcium carbonate; Net photosynthesis rate, oxygen; Net photosynthesis rate, standard deviation; Ocean acidification; refugia; Respiration rate, oxygen, per dry mass; Respiration rate, oxygen, standard deviation; Species; Treatment; Treatment: pH

Type: Dataset

Format: text/tab-separated-values, 110 data points

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