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Marine Amphipoda and environmental occurrence around Iceland (2021)

Lörz, Anne-Nina ; Brix, Saskia ; Oldeland, Jens ; [et al.]

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Publication Date: 2023-01-13

Description: The distribution and diversity of amphipod crustaceans of Icelandic waters, in water depths between 18-3700 m, was examined and how it relates to environmental parameters and depth. Data on amphipod occurrence and abundance were collated from the historical literature (Ingolf Expedition, 1895-96), as well as recent expeditions (1998-2018) such as BioIce (Benthic invertebrates of Icelandic waters) and IceAge (Icelandic marine Animals: Genetics and Ecology, www.iceage-project.org) resulting in 355 amphipod species amongst 71,108 individuals from 532 localities. Samples were taken by a number of trawled sampling devices, including different types of dredges and sledges, as well as Remotely Operated Vehicle (ROV). A 1 ° hexagonal grid was constructed in to map the distribution of the amphipod species alongside twelve environmental factors retrieved from the Bio-Oracle 2.1 database. Due to strong autocorrelation of some of these factors, the analysis was limited to a set of eight variables: depth, pH, phytobiomass, velocity, dissolved oxygen, dissolved iron, salinity, and seabed temperature. Based on these faunistic and environmental data, four biogeographical clusters could be identified: a coastal cluster, a species cluster along the borders of the Greenland-Iceland-Faroe Ridge (GIFR), which separates the deep-sea basins north and south of Iceland, a cluster that is limited to the deep sea to the north of the GIFR, and one that is restricted to the deep-sea south of the GIFR. Diversity as measured by Hill numbers differed considerably between these clusters, with the diversity of the shallow cluster (Coastal and GIFR) to be higher compared to the two deep-sea cluster (Deep North and Deep South). Analysing diversity across a depth gradient, diversity showed a hump-shaped curve with diversity peaking at upper slope (500 m) depth. Depth, salinity and temperature of the seabed were identified as the main parameters to shape the distribution of amphipods around Iceland. Perceived diversity and distribution patterns were discussed with regard to the influence of historical (e.g. oceanography, climatic conditions) and contemporary environmental factors.

Keywords: Amphipoda Atlantic Crustacea; Ecology & Environment; North; Peracarida; Zoology

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Format: application/zip, 2 datasets

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Data set on restoration projects of coastal marine habitats reported worldwide (2020)

Duarte, Carlos Manuel ; Devassy, R P ; Predragovic, M ; [et al.]

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Publication Date: 2023-01-30

Description: Data set on restoration projects of coastal marina habitats reported worldwide. The data set includes projects on mangroves, seagrass, saltmarshes, oyster reefs and tropical coral reefs, and include details on the location of the restoration project, the year the restoration project was established or reported, and the source of the information.

Keywords: coral reefs; mangroves; oyster reefs; restoration; saltmarshes; Seagrass

Type: Dataset

Format: text/csv, 278.6 kBytes

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Environmental parameters including coordinates for 532 stations in icelandic waters (2021)

Lörz, Anne-Nina ; Brix, Saskia ; Oldeland, Jens ; [et al.]

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Publication Date: 2023-05-12

Keywords: 7709-62; 7709-66; 7709-72; 7709-73; 7709-85; Agassiz Trawl; AGT; Amphipoda Atlantic Crustacea; Arctic Ocean; BC; BIOFAR_St113; BIOFAR_St124; BIOFAR_St15; BIOFAR_St158; BIOFAR_St167; BIOFAR_St168; BIOFAR_St169; BIOFAR_St170; BIOFAR_St171; BIOFAR_St172; BIOFAR_St189; BIOFAR_St19; BIOFAR_St261; BIOFAR_St264; BIOFAR_St267; BIOFAR_St27; BIOFAR_St271; BIOFAR_St274; BIOFAR_St28; BIOFAR_St32; BIOFAR_St380; BIOFAR_St382; BIOFAR_St417; BIOFAR_St421; BIOFAR_St458; BIOFAR_St459; BIOFAR_St481; BIOFAR_St489; BIOFAR_St490; BIOFAR_St493; BIOFAR_St494; BIOFAR_St495; BIOFAR_St499; BIOFAR_St500; BIOFAR_St514; BIOFAR_St515; BIOFAR_St516; BIOFAR_St517; BIOFAR_St522; BIOFAR_St524; BIOFAR_St610; BIOFAR_St65; BIOFAR_St68; BIOFAR_St689; BIOFAR_St691; BIOFAR_St698; BIOFAR_St699; BIOFAR_St70; BIOFAR_St705; BIOFAR_St719; BIOFAR_St73; BIOFAR_St730; BIOFAR_St731; BIOFAR_St736; BIOFAR_St739; BIOFAR_St742; BIOFAR_St744; BIOFAR_St75; BIOFAR_St750; BIOFAR_St770; BIOFAR_St82; BIOFAR_St88; BIOFAR_St89; BIOFAR_St9014; BIOFAR_St95; BIOICE_St2004; BIOICE_St2005; BIOICE_St2006; BIOICE_St2009; BIOICE_St2023; BIOICE_St2042; BIOICE_St2044; BIOICE_St2046; BIOICE_St2049; BIOICE_St2051; BIOICE_St2056; BIOICE_St2057; BIOICE_St2058; BIOICE_St2060; BIOICE_St2061; BIOICE_St2062; BIOICE_St2064; BIOICE_St2067; BIOICE_St2070; BIOICE_St2074; BIOICE_St2075; BIOICE_St2077; BIOICE_St2081; BIOICE_St2086; BIOICE_St2087; BIOICE_St2088; BIOICE_St2089; BIOICE_St2090; BIOICE_St2091; BIOICE_St2093; BIOICE_St2094; BIOICE_St2096; BIOICE_St2097; BIOICE_St2099; BIOICE_St2100; BIOICE_St2103; BIOICE_St2107; BIOICE_St2108; BIOICE_St2110; BIOICE_St2111; BIOICE_St2113; BIOICE_St2114; BIOICE_St2116; BIOICE_St2117; BIOICE_St2118; BIOICE_St2119; BIOICE_St2122; BIOICE_St2124; BIOICE_St2126; BIOICE_St2128; BIOICE_St2129; BIOICE_St2131; BIOICE_St2132; BIOICE_St2134; BIOICE_St2135; BIOICE_St2136; BIOICE_St2137; BIOICE_St2140; BIOICE_St2142; BIOICE_St2143; BIOICE_St2145; BIOICE_St2146; BIOICE_St2147; BIOICE_St2149; BIOICE_St2150; BIOICE_St2152; BIOICE_St2154; BIOICE_St2156; BIOICE_St2161; BIOICE_St2164; BIOICE_St2167; BIOICE_St2170; BIOICE_St2172; BIOICE_St2175; BIOICE_St2177; BIOICE_St2178; BIOICE_St2180; BIOICE_St2201; BIOICE_St2207; BIOICE_St2210; BIOICE_St2212; BIOICE_St2213; BIOICE_St2215; BIOICE_St2219; BIOICE_St2221; BIOICE_St2226; BIOICE_St2229; BIOICE_St2233; BIOICE_St2236; BIOICE_St2237; BIOICE_St2255; BIOICE_St2257; BIOICE_St2265; BIOICE_St2268; BIOICE_St2273; BIOICE_St2282; BIOICE_St2285; BIOICE_St2288; BIOICE_St2299; BIOICE_St2303; BIOICE_St2308; BIOICE_St2311; BIOICE_St2314; BIOICE_St2317; BIOICE_St2318; BIOICE_St2319; BIOICE_St2321; BIOICE_St2322; BIOICE_St2323; BIOICE_St2324; BIOICE_St2325; BIOICE_St2327; BIOICE_St2328; BIOICE_St2330; BIOICE_St2332; BIOICE_St2334; BIOICE_St2337; BIOICE_St2340; BIOICE_St2342; BIOICE_St2345; BIOICE_St2346; BIOICE_St2348; BIOICE_St2349; BIOICE_St2352; BIOICE_St2355; BIOICE_St2356; BIOICE_St2357; BIOICE_St2358; BIOICE_St2359; BIOICE_St2360; BIOICE_St2362; BIOICE_St2363; BIOICE_St2364; BIOICE_St2366; BIOICE_St2367; BIOICE_St2368; BIOICE_St2373; BIOICE_St2374; BIOICE_St2376; BIOICE_St2379; BIOICE_St2380; BIOICE_St2381; BIOICE_St2382; BIOICE_St2393; BIOICE_St2398; BIOICE_St2401; BIOICE_St2403; BIOICE_St2404; BIOICE_St2406; BIOICE_St2407; BIOICE_St2409; BIOICE_St2410; BIOICE_St2412; BIOICE_St2414; BIOICE_St2415; BIOICE_St2417; BIOICE_St2418; BIOICE_St2420; BIOICE_St2423; BIOICE_St2424; BIOICE_St2426; BIOICE_St2427; BIOICE_St2429; BIOICE_St2430; BIOICE_St2431; BIOICE_St2434; BIOICE_St2435; BIOICE_St2438; BIOICE_St2440; BIOICE_St2441; BIOICE_St2451; BIOICE_St2454; BIOICE_St2456; BIOICE_St2457; BIOICE_St2459; BIOICE_St2460; BIOICE_St2463; BIOICE_St2466; BIOICE_St2469; BIOICE_St2472; BIOICE_St2474; BIOICE_St2475; BIOICE_St2480; BIOICE_St2490; BIOICE_St2491; BIOICE_St2493; BIOICE_St2497; BIOICE_St2499; BIOICE_St2501; BIOICE_St2502; BIOICE_St2507; BIOICE_St2508; BIOICE_St2509; BIOICE_St2512; BIOICE_St2514; BIOICE_St2516; BIOICE_St2518; BIOICE_St2522; BIOICE_St2524; BIOICE_St2526; BIOICE_St2527; BIOICE_St2531; BIOICE_St2540; BIOICE_St2545; BIOICE_St2554; BIOICE_St2555; BIOICE_St2564; BIOICE_St2566; BIOICE_St2568; BIOICE_St2570; BIOICE_St2573; BIOICE_St2575; BIOICE_St2576; BIOICE_St2578; BIOICE_St2579; BIOICE_St2581; BIOICE_St2583; BIOICE_St2585; BIOICE_St2588; BIOICE_St2589; BIOICE_St2591; BIOICE_St2594; BIOICE_St2595; BIOICE_St2597; BIOICE_St2606; BIOICE_St2610; BIOICE_St2613; BIOICE_St2616; BIOICE_St2619; BIOICE_St2622; BIOICE_St2629; BIOICE_St2637; BIOICE_St2638; BIOICE_St2648; BIOICE_St2652; BIOICE_St2655; BIOICE_St2660; BIOICE_St2669; BIOICE_St2673; BIOICE_St2675; BIOICE_St2678; BIOICE_St2682; BIOICE_St2692; BIOICE_St2697; BIOICE_St2698; BIOICE_St2700; BIOICE_St2701; BIOICE_St2704; BIOICE_St2707; BIOICE_St2712; BIOICE_St2713; BIOICE_St2717; BIOICE_St2719; BIOICE_St2720; BIOICE_St2726; BIOICE_St2736; BIOICE_St2743; BIOICE_St2745; BIOICE_St2749; BIOICE_St2750; BIOICE_St2751; BIOICE_St2756; BIOICE_St2758; BIOICE_St2759; BIOICE_St2776; BIOICE_St2777; BIOICE_St2779; BIOICE_St2783; BIOICE_St2787; BIOICE_St2789; BIOICE_St2790; BIOICE_St2814; BIOICE_St2823; BIOICE_St2824; BIOICE_St2829; BIOICE_St2830; BIOICE_St2844; BIOICE_St2846; BIOICE_St2849; BIOICE_St2856; BIOICE_St2859; BIOICE_St2860; BIOICE_St2863; BIOICE_St2864; BIOICE_St2867; BIOICE_St2868; BIOICE_St2900; BIOICE_St2904; BIOICE_St2907; BIOICE_St2909; BIOICE_St2912; BIOICE_St2920; BIOICE_St2921; BIOICE_St2923; BIOICE_St2926; BIOICE_St2930; BIOICE_St2932; BIOICE_St2934; BIOICE_St2937; BIOICE_St2939; BIOICE_St2940; BIOICE_St2943; BIOICE_St2944; BIOICE_St2951; BIOICE_St2959; BIOICE_St2976; BIOICE_St2979; BIOICE_St2981; BIOICE_St2983; BIOICE_St2986; BIOICE_St2998; BIOICE_St2999; BIOICE_St3004; BIOICE_St3023; BIOICE_St3025; BIOICE_St3028; BIOICE_St3029; BIOICE_St3032; BIOICE_St3033; BIOICE_St3039; BIOICE_St3043; BIOICE_St3046; BIOICE_St3047; BIOICE_St3048; BIOICE_St3050; BIOICE_St3054; BIOICE_St3056; BIOICE_St3061; BIOICE_St3062; BIOICE_St3067; BIOICE_St3069; BIOICE_St3099; BIOICE_St3108; BIOICE_St3115; BIOICE_St3154; BIOICE_St3158; BIOICE_St3170; BIOICE_St3236; BIOICE_St3246; BIOICE_St3247; BIOICE_St3249; BIOICE_St3250; BIOICE_St3275; BIOICE_St3276; BIOICE_St3280; BIOICE_St3501; BIOICE_St3510; BIOICE_St3515; Box corer; Chlorophyll total; Cruise/expedition; Current velocity; Davis Strait; DEPTH, water; Dredge; DRG; EBS; Ecology & Environment; Epibenthic sledge; Event label; extracted from Bio-Oracle 2.1; Gear; Grab; GRAB; Greenland Sea; IceAGE_1006_1; IceAGE_1010_1; IceAGE_1017_1; IceAGE_1019_1; IceAGE_1032_1; IceAGE_1033_1; IceAGE_1054_1; IceAGE_1057_1; IceAGE_1082_1; IceAGE_1086_1; IceAGE_1104_1; IceAGE_1119_1; IceAGE_1123_1; IceAGE_1132_1; IceAGE_1155_1; IceAGE_1159_1; IceAGE_1168_1; IceAGE_1172_1; IceAGE_1181_1; IceAGE_1184_1; IceAGE_1194_1; IceAGE_1219_1; IceAGE_1222_1; IceAGE_963_1; IceAGE_967_1; IceAGE_979_1; IceAGE_983_1; IceAGE-2_866_7; IceAGE-2_867_1; IceAGE-2_868_3; IceAGE-2_869_2; IceAGE-2_870_4; IceAGE-2_872_4; IceAGE-2_876_5; IceAGE-2_878_1; IceAGE-2_879_5; IceAGE-2_880_2; IceAGE-2_880_3; IceAGE-3_106; IceAGE-3_30; IceAGE-3_37; IceAGE-3_39; IceAGE-3_5; IceAGE-3_55; IceAGE-3_73; IceAGE-3_79; IceAGE-3_85; IceAGE-3_97; IceAGE-RR_106; IceAGE-RR_111; IceAGE-RR_124; IceAGE-RR_127; IceAGE-RR_136; IceAGE-RR_137; IceAGE-RR_149; IceAGE-RR_170; IceAGE-RR_171; IceAGE-RR_188; IceAGE-RR_212; IceAGE-RR_213; IceAGE-RR_216; IceAGE-RR_225; IceAGE-RR_228; IceAGE-RR_24; IceAGE-RR_35; IceAGE-RR_4; IceAGE-RR_64; IceAGE-RR_67; IceAGE-RR_7; IceAGE-RR_80; IceAGE-RR_83; IceAGE-RR_9; Iceland; Iceland Sea; Ingolf; INGOLF-101; INGOLF-102; INGOLF-103; INGOLF-104; INGOLF-105; INGOLF-112; INGOLF-113; INGOLF-115; INGOLF-116; INGOLF-117; INGOLF-118; INGOLF-120; INGOLF-124; INGOLF-126; INGOLF-127; INGOLF-128; INGOLF-138; INGOLF-139; INGOLF-140; INGOLF-143; INGOLF-15; INGOLF-4; INGOLF-40; INGOLF-44; INGOLF-58; INGOLF-6; INGOLF-7; INGOLF-78; INGOLF-80; INGOLF-87; INGOLF-90; INGOLF-95; INGOLF-96; INGOLF-98; Ingolf-Expedition; Iron; Latitude of event; Longitude of

Type: Dataset

Format: text/tab-separated-values, 7979 data points

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Community matrix of amphipod species for 532 stations in icelandic waters (2021)

Lörz, Anne-Nina ; Brix, Saskia ; Oldeland, Jens ; [et al.]

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Publication Date: 2023-07-09

Keywords: 7709-62; 7709-66; 7709-72; 7709-73; 7709-85; Abludomelita gladiosa; Abludomelita obtusata; Acanthonotozoma cristatum; Acanthonotozoma serratum; Acanthostepheia malmgreni; Aceroides latipes; Aeginella spinosa; Aeginina longicornis; Agassiz Trawl; AGT; Ambasia atlantica; Ampelisca aequicornis; Ampelisca amblyops; Ampelisca compacta; Ampelisca eschrichtii; Ampelisca gibba; Ampelisca islandica; Ampelisca macrocephala; Ampelisca odontoplax; Ampelisca sp.; Ampelisca uncinata; Amphilochoides boecki; Amphilochoides serratipes; Amphilochus anoculus; Amphilochus hamatus; Amphilochus manudens; Amphilochus sp.; Amphilochus tenuimanus; Amphipoda Atlantic Crustacea; Amphithopsis longicaudata; Andaniella pectinata; Andaniexis abyssi; Andaniexis lupus; Andaniexis sp.; Andaniopsis nordlandica; Andaniopsis pectinata; Anonyx sp.; Apherusa glacialis; Apherusa sarsii; Apherusa sp.; Arctic Ocean; Argissa hamatipes; Arrhinopsis sp.; Arrhis phyllonyx; Arrhis sp.; Astyra abyssi; Astyra sp.; Austrosyrrhoe septentrionalis; Austrosyrrhoe sp.; Autonoe borealis; Bathymedon longimanus; Bathymedon obtusifrons; Bathymedon saussurei; Bathymedon sp.; BC; BIOFAR_St113; BIOFAR_St124; BIOFAR_St15; BIOFAR_St158; BIOFAR_St167; BIOFAR_St168; BIOFAR_St169; BIOFAR_St170; BIOFAR_St171; BIOFAR_St172; BIOFAR_St189; BIOFAR_St19; BIOFAR_St261; BIOFAR_St264; BIOFAR_St267; BIOFAR_St27; BIOFAR_St271; BIOFAR_St274; BIOFAR_St28; BIOFAR_St32; BIOFAR_St380; BIOFAR_St382; BIOFAR_St417; BIOFAR_St421; BIOFAR_St458; BIOFAR_St459; BIOFAR_St481; BIOFAR_St489; BIOFAR_St490; BIOFAR_St493; BIOFAR_St494; BIOFAR_St495; BIOFAR_St499; BIOFAR_St500; BIOFAR_St514; BIOFAR_St515; BIOFAR_St516; BIOFAR_St517; BIOFAR_St522; BIOFAR_St524; BIOFAR_St610; BIOFAR_St65; BIOFAR_St68; BIOFAR_St689; BIOFAR_St691; BIOFAR_St698; BIOFAR_St699; BIOFAR_St70; BIOFAR_St705; BIOFAR_St719; BIOFAR_St73; BIOFAR_St730; BIOFAR_St731; BIOFAR_St736; BIOFAR_St739; BIOFAR_St742; BIOFAR_St744; BIOFAR_St75; BIOFAR_St750; BIOFAR_St770; BIOFAR_St82; BIOFAR_St88; BIOFAR_St89; BIOFAR_St9014; BIOFAR_St95; BIOICE_St2004; BIOICE_St2005; BIOICE_St2006; BIOICE_St2009; BIOICE_St2023; BIOICE_St2042; BIOICE_St2044; BIOICE_St2046; BIOICE_St2049; BIOICE_St2051; BIOICE_St2056; BIOICE_St2057; BIOICE_St2058; BIOICE_St2060; BIOICE_St2061; BIOICE_St2062; BIOICE_St2064; BIOICE_St2067; BIOICE_St2070; BIOICE_St2074; BIOICE_St2075; BIOICE_St2077; BIOICE_St2081; BIOICE_St2086; BIOICE_St2087; BIOICE_St2088; BIOICE_St2089; BIOICE_St2090; BIOICE_St2091; BIOICE_St2093; BIOICE_St2094; BIOICE_St2096; BIOICE_St2097; BIOICE_St2099; BIOICE_St2100; BIOICE_St2103; BIOICE_St2107; BIOICE_St2108; BIOICE_St2110; BIOICE_St2111; BIOICE_St2113; BIOICE_St2114; BIOICE_St2116; BIOICE_St2117; BIOICE_St2118; BIOICE_St2119; BIOICE_St2122; BIOICE_St2124; BIOICE_St2126; BIOICE_St2128; BIOICE_St2129; BIOICE_St2131; BIOICE_St2132; BIOICE_St2134; BIOICE_St2135; BIOICE_St2136; BIOICE_St2137; BIOICE_St2140; BIOICE_St2142; BIOICE_St2143; BIOICE_St2145; BIOICE_St2146; BIOICE_St2147; BIOICE_St2149; BIOICE_St2150; BIOICE_St2152; BIOICE_St2154; BIOICE_St2156; BIOICE_St2161; BIOICE_St2164; BIOICE_St2167; BIOICE_St2170; BIOICE_St2172; BIOICE_St2175; BIOICE_St2177; BIOICE_St2178; BIOICE_St2180; BIOICE_St2201; BIOICE_St2207; BIOICE_St2210; BIOICE_St2212; BIOICE_St2213; BIOICE_St2215; BIOICE_St2219; BIOICE_St2221; BIOICE_St2226; BIOICE_St2229; BIOICE_St2233; BIOICE_St2236; BIOICE_St2237; BIOICE_St2255; BIOICE_St2257; BIOICE_St2265; BIOICE_St2268; BIOICE_St2273; BIOICE_St2282; BIOICE_St2285; BIOICE_St2288; BIOICE_St2299; BIOICE_St2303; BIOICE_St2308; BIOICE_St2311; BIOICE_St2314; BIOICE_St2317; BIOICE_St2318; BIOICE_St2319; BIOICE_St2321; BIOICE_St2322; BIOICE_St2323; BIOICE_St2324; BIOICE_St2325; BIOICE_St2327; BIOICE_St2328; BIOICE_St2330; BIOICE_St2332; BIOICE_St2334; BIOICE_St2337; BIOICE_St2340; BIOICE_St2342; BIOICE_St2345; BIOICE_St2346; BIOICE_St2348; BIOICE_St2349; BIOICE_St2352; BIOICE_St2355; BIOICE_St2356; BIOICE_St2357; BIOICE_St2358; BIOICE_St2359; BIOICE_St2360; BIOICE_St2362; BIOICE_St2363; BIOICE_St2364; BIOICE_St2366; BIOICE_St2367; BIOICE_St2368; BIOICE_St2373; BIOICE_St2374; BIOICE_St2376; BIOICE_St2379; BIOICE_St2380; BIOICE_St2381; BIOICE_St2382; BIOICE_St2393; BIOICE_St2398; BIOICE_St2401; BIOICE_St2403; BIOICE_St2404; BIOICE_St2406; BIOICE_St2407; BIOICE_St2409; BIOICE_St2410; BIOICE_St2412; BIOICE_St2414; BIOICE_St2415; BIOICE_St2417; BIOICE_St2418; BIOICE_St2420; BIOICE_St2423; BIOICE_St2424; BIOICE_St2426; BIOICE_St2427; BIOICE_St2429; BIOICE_St2430; BIOICE_St2431; BIOICE_St2434; BIOICE_St2435; BIOICE_St2438; BIOICE_St2440; BIOICE_St2441; BIOICE_St2451; BIOICE_St2454; BIOICE_St2456; BIOICE_St2457; BIOICE_St2459; BIOICE_St2460; BIOICE_St2463; BIOICE_St2466; BIOICE_St2469; BIOICE_St2472; BIOICE_St2474; BIOICE_St2475; BIOICE_St2480; BIOICE_St2490; BIOICE_St2491; BIOICE_St2493; BIOICE_St2497; BIOICE_St2499; BIOICE_St2501; BIOICE_St2502; BIOICE_St2507; BIOICE_St2508; BIOICE_St2509; BIOICE_St2512; BIOICE_St2514; BIOICE_St2516; BIOICE_St2518; BIOICE_St2522; BIOICE_St2524; BIOICE_St2526; BIOICE_St2527; BIOICE_St2531; BIOICE_St2540; BIOICE_St2545; BIOICE_St2554; BIOICE_St2555; BIOICE_St2564; BIOICE_St2566; BIOICE_St2568; BIOICE_St2570; BIOICE_St2573; BIOICE_St2575; BIOICE_St2576; BIOICE_St2578; BIOICE_St2579; BIOICE_St2581; BIOICE_St2583; BIOICE_St2585; BIOICE_St2588; BIOICE_St2589; BIOICE_St2591; BIOICE_St2594; BIOICE_St2595; BIOICE_St2597; BIOICE_St2606; BIOICE_St2610; BIOICE_St2613; BIOICE_St2616; BIOICE_St2619; BIOICE_St2622; BIOICE_St2629; BIOICE_St2637; BIOICE_St2638; BIOICE_St2648; BIOICE_St2652; BIOICE_St2655; BIOICE_St2660; BIOICE_St2669; BIOICE_St2673; BIOICE_St2675; BIOICE_St2678; BIOICE_St2682; BIOICE_St2692; BIOICE_St2697; BIOICE_St2698; BIOICE_St2700; BIOICE_St2701; BIOICE_St2704; BIOICE_St2707; BIOICE_St2712; BIOICE_St2713; BIOICE_St2717; BIOICE_St2719; BIOICE_St2720; BIOICE_St2726; BIOICE_St2736; BIOICE_St2743; BIOICE_St2745; BIOICE_St2749; BIOICE_St2750; BIOICE_St2751; BIOICE_St2756; BIOICE_St2758; BIOICE_St2759; BIOICE_St2776; BIOICE_St2777; BIOICE_St2779; BIOICE_St2783; BIOICE_St2787; BIOICE_St2789; BIOICE_St2790; BIOICE_St2814; BIOICE_St2823; BIOICE_St2824; BIOICE_St2829; BIOICE_St2830; BIOICE_St2844; BIOICE_St2846; BIOICE_St2849; BIOICE_St2856; BIOICE_St2859; BIOICE_St2860; BIOICE_St2863; BIOICE_St2864; BIOICE_St2867; BIOICE_St2868; BIOICE_St2900; BIOICE_St2904; BIOICE_St2907; BIOICE_St2909; BIOICE_St2912; BIOICE_St2920; BIOICE_St2921; BIOICE_St2923; BIOICE_St2926; BIOICE_St2930; BIOICE_St2932; BIOICE_St2934; BIOICE_St2937; BIOICE_St2939; BIOICE_St2940; BIOICE_St2943; BIOICE_St2944; BIOICE_St2951; BIOICE_St2959; BIOICE_St2976; BIOICE_St2979; BIOICE_St2981; BIOICE_St2983; BIOICE_St2986; BIOICE_St2998; BIOICE_St2999; BIOICE_St3004; BIOICE_St3023; BIOICE_St3025; BIOICE_St3028; BIOICE_St3029; BIOICE_St3032; BIOICE_St3033; BIOICE_St3039; BIOICE_St3043; BIOICE_St3046; BIOICE_St3047; BIOICE_St3048; BIOICE_St3050; BIOICE_St3054; BIOICE_St3056; BIOICE_St3061; BIOICE_St3062; BIOICE_St3067; BIOICE_St3069; BIOICE_St3099; BIOICE_St3108; BIOICE_St3115; BIOICE_St3154; BIOICE_St3158; BIOICE_St3170; BIOICE_St3236; BIOICE_St3246; BIOICE_St3247; BIOICE_St3249; BIOICE_St3250; BIOICE_St3275; BIOICE_St3276; BIOICE_St3280; BIOICE_St3501; BIOICE_St3510; BIOICE_St3515; Box corer; Bruzelia sp.; Bruzelia tuberculata; Byblis crassicornis; Byblis erythrops; Byblis gaimardii; Byblis medialis; Byblis minuticornis; Byblisoides bellansantiniae; Byblis sp.; Calliopius laeviusculus; Camacho faroensis; Caprella ciliata; Caprella dubia; Caprella microtuberculata; Caprella rinki; Caprella septentrionalis; Chevreuxius grandimanus; Cleippides bicuspis; Cleippides quadricuspis; Cleippides tricuspis; Cleonardopsis sp.; Cleonardo sp.; Corophiidira sp.; Cressa carinata; Cressa jeanjusti; Cressa minuta; Cressa quinquedentata; Cressina monocuspis; Cruise/expedition; Davis Strait; Deflexilodes norvegicus; Deflexilodes rostratus; Deflexilodes subnudus; Deflexilodes tenuirostratus; Deflexilodes tesselatus; Deflexilodes

Type: Dataset

Format: text/tab-separated-values, 190455 data points

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10 daily surface measurements over 90m transect, SSA, Density and Accumulation, from EastGRIP summer (May-August) of 2016-2019 (2022)

Steen-Larsen, Hans Christian ; Hörhold, Maria ; Kipfstuhl, Sepp ; [et al.]

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Publication Date: 2023-07-29

Description: Dataset containing surface snow measurements of snow specific surface area (SSA), snow density and snow accumulation. Surface samples were taken from the surface 2.5cm of snow. SSA measurements were determined using an Ice Cube measuring device (Zuanon, 2013). Snow density was measured from the SSA samples with a fixed volume. Snow accumulation describes the change in surface height at each sample site. All measured parameters have 10 daily samples taken at 10m intervals over a 90m transect. Sampling was carried out daily between May and August of 2016-2019, at approximately 24hr time intervals. All measurements were taken at the East Greenland Ice Core Project site (EastGRIP) situated in the accumulation zone of the Greenland Ice Sheet.

Keywords: Accumulation; Accumulation of snow; AWI_Envi; Calculated; calibrated; DATE/TIME; density; Density, snow; East Greenland Ice-core Project; EastGRIP; EastGRIP_transect; EGRIP; Greenland; Measured; Polar Terrestrial Environmental Systems @ AWI; Signals from the Surface Snow: Post-Depositional Processes Controlling the Ice Core Isotopic Fingerprint; SNOW; Snow/ice sample; Snow depth; SNOWISO; Specific surface area, snow; SSA; surface snow

Type: Dataset

Format: text/tab-separated-values, 8118 data points

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Limnological properties of thermokarst lakes in Central Yakutia sampled between 2018-2019 (2020)

Hughes-Allen, Lara ; Bouchard, Frédéric ; Séjourné, Antoine ; [et al.]

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Publication Date: 2023-07-19

Description: This dataset compiles selected limnological properties of a series of thermokarst (thaw) lakes in Central Yakutia (Eastern Siberia). These properties were measured during fall 2018 (September), winter 2019 (March-April), spring 2019 (May), and summer 2019 (August). These data span four seasons (Fall, Winter, Spring, and Summer) 2018-2019. The lake type designation is based on field observations, past radiocarbon dating of lake sediments, geochemical signatures of lake waters, and a multiple-stage development model of thermokarst lakes. Data were collected at the surface (~ 30 cm depth) from lake shores. Specific conductivity (accuracy ±1% of reading), temperature (accuracy ±0.2°C), dissolved oxygen (accuracy ±1% of reading or 1% saturation) and pH (accuracy ±0.2) were measured using a YSI Pro DSS multiprobe sensor. Water samples were collected to analyze dissolved organic carbon (DOC). Samples were filtered using baked glass fiber filters (Whatman GF/F, 0. 7µm), acidified to pH 2 with ultra-pure HCl and stored in baked glass vials. DOC concentration was measured using a TOC-5000A analyzer (Shimadzu, Japan). The quantification limit was 1 mg L-1. Above this value, the analytical uncertainty was estimated at ±0.1 mg L-1. Reference material included ION-915 ([DOC]= 1.37 ± 0.41mg C L-1) and ION 96.4 ([DOC]= 4.64 ± 0.70 mg C L-1) (Environment and Climate Change Canada, Canada).

Keywords: Carbon, organic, dissolved; Central_Yakutia_thermokast_lakes; Central Yakutia; Conductivity, specific; Dissolved Organic Carbon; dissolved oxygen; Lake; LAKE; Lake type; LATITUDE; limnology; LONGITUDE; Oxygen, dissolved; Permafrost; pH; Sampling lake; Season; Temperature; Temperature, water; thermokarst lakes; TOC-5000A analyzer, Shimadzu, Japan; Year of observation; YSI Pro DSS multiprobe sensor

Type: Dataset

Format: text/tab-separated-values, 939 data points

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Contamination and invertebrate presence on food transported to Antarctica (2011)

Hughes, Kevin A ; Lee, Jennifer E ; Tsujimoto, Megumu ; [et al.]

PANGAEA

In: Supplement to: Hughes, Kevin A; Lee, Jennifer E; Tsujimoto, Megumu; Imura, Satoshi; Bergstrom, Dana Michelle; Ware, Chris; Lebouvier, Marc; Huiskes, Ad H L; Gremmen, Niek J M; Frenot, Yves; Bridge, Paul D; Chown, Steven L (2011): Food for thought: Risks of non-native species transfer to the Antarctic region with fresh produce. Biological Conservation, 144(5), 1682-1689, https://doi.org/10.1016/j.biocon.2011.03.001

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Publication Date: 2023-12-13

Description: To understand fully the risk of biological invasions, it is necessary to quantify propagule pressure along all introduction pathways. In the Antarctic region, importation of fresh produce is a potentially high risk, but as yet unquantified pathway. To address this knowledge gap, 〉11,250 fruit and vegetables sent to nine research stations in Antarctica and the sub-Antarctic islands, were examined for associated soil, invertebrates and microbial decomposition. Fifty-one food types were sourced from c. 130 locations dispersed across all six of the Earth's inhabited continents. On average, 12% of food items had soil on their surface, 28% showed microbial infection resulting in rot and more than 56 invertebrates were recorded, mainly from leafy produce. Approximately 30% of identified fungi sampled from infected foods were not recorded previously from within the Antarctic region, although this may reflect limited knowledge of Antarctic fungal diversity. The number of non-native flying invertebrates caught within the Rothera Research Station food storage area was linked closely with the level of fresh food resupply by ship and aircraft. We conclude by presenting practical biosecurity measures to reduce the risk of non-native species introductions to Antarctica associated with fresh foods.

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

Type: Dataset

Format: application/zip, 4 datasets

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Seed dispersal characteristics to polar regions by means of visitors (2012)

Chown, Steven L ; Huiskes, Ad H L ; Gremmen, Niek J M ; [et al.]

PANGAEA

In: Supplement to: Chown, Steven L; Huiskes, Ad H L; Gremmen, Niek J M; Lee, Jennifer E; Terauds, Aleks; Crosbie, Kim; Frenot, Yves; Hughes, Kevin A; Imura, Satoshi; Kiefer, K; Lebouvier, Marc; Raymond, Ben; Tsujimoto, Megumu; Ware, Chris; Van de Vijver, Bart; Bergstrom, Dana Michelle (2012): Continent-wide risk assessment for the establishment of nonindigenous species in Antarctica. Proceedings of the National Academy of Sciences, 109(13), 4938-4943, https://doi.org/10.1073/pnas.1119787109

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Publication Date: 2023-12-13

Description: Invasive alien species are among the primary causes of biodiversity change globally, with the risks thereof broadly understood for most regions of the world. They are similarly thought to be among the most significant conservation threats to Antarctica, especially as climate change proceeds in the region. However, no comprehensive, continent-wide evaluation of the risks to Antarctica posed by such species has been undertaken. Here we do so by sampling, identifying, and mapping the vascular plant propagules carried by all categories of visitors to Antarctica during the International Polar Year's first season (2007-2008) and assessing propagule establishment likelihood based on their identity and origins and on spatial variation in Antarctica's climate. For an evaluation of the situation in 2100, we use modeled climates based on the Intergovernmental Panel on Climate Change's Special Report on Emissions Scenarios Scenario A1B [Nakicenovic N, Swart R, eds (2000) Special Report on Emissions Scenarios: A Special Report of Working Group III of the Intergovernmental Panel on Climate Change (Cambridge University Press, Cambridge, UK)]. Visitors carrying seeds average 9.5 seeds per person, although as vectors, scientists carry greater propagule loads than tourists. Annual tourist numbers (~33,054) are higher than those of scientists (~7,085), thus tempering these differences in propagule load. Alien species establishment is currently most likely for the Western Antarctic Peninsula. Recent founder populations of several alien species in this area corroborate these findings. With climate change, risks will grow in the Antarctic Peninsula, Ross Sea, and East Antarctic coastal regions. Our evidence-based assessment demonstrates which parts of Antarctica are at growing risk from alien species that may become invasive and provides the means to mitigate this threat now and into the future as the continent's climate changes.

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

Type: Dataset

Format: application/zip, 4 datasets

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(Tables 1,2) Viability of Poa trivialis seeds transported to Antarctica from different locations (2010)

Hughes, Kevin A ; Lee, Jennifer E ; Ware, Chris ; [et al.]

PANGAEA

In: Supplement to: Hughes, Kevin A; Lee, Jennifer E; Ware, Chris; Kiefer, K; Bergstrom, Dana Michelle (2010): Impact of anthropogenic transportation to Antarctica on alien seed viability. Polar Biology, 33(8), 1125-1130, https://doi.org/10.1007/s00300-010-0801-4

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Publication Date: 2023-12-13

Description: Antarctic ecosystems are at risk from the introduction of invasive species. The first step in the process of invasion is the transportation of alien species to Antarctic in a viable state. However, the effect of long-distance human-mediated dispersal, over different time-scales, on propagule viability is not well known. We assessed the viability of Poa trivialis seeds transported to Antarctica from the UK, South Africa and Australia by ship or by ship and aircraft. Following transportation to the Antarctic Treaty area, no reduction in seed viability was found, despite journey times lasting up to 284 days and seeds experiencing temperatures as low as -1.5°C. This work confirms that human-mediated transport may overcome the dispersal barrier for some propagules, and highlights the need for effective pre-departure biosecurity measures.

Keywords: Comment; Description; Distance; Duration, number of days; International Polar Year (2007-2008); IPY; Location; Name; Seed viability; Standard deviation; Temperature, air; Temperature, air, maximum; Temperature, air, minimum; Temperature, air, standard deviation

Type: Dataset

Format: text/tab-separated-values, 109 data points

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Calibrated ages of Piyashiri (PYR) peat core from Japan (2021)

Hughes, Paul D M

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Publication Date: 2023-12-12

Description: Calibrated ages of a high-resolution peat core from the Past Global Changes - Carbon in Peat on EArth through Time (PAGES_C-PEAT) Project.

Keywords: Age, 14C calibrated, Bacon 2.2 (Blaauw and Christen, 2011); Age, 14C calibrated, OxCal 4.2.4, P sequence deposition model; Calendar age; Calendar age, maximum/old; Calendar age, minimum/young; C-PEAT; DEPTH, sediment/rock; Japan; PAGES_C-PEAT; Past Global Changes - Carbon in Peat on EArth through Time; PEATC; Peat corer; Peatland; Piyashiri; PYR

Type: Dataset

Format: text/tab-separated-values, 852 data points

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