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  • 1
    facet.materialart.
    Unknown
    Oceanographic parameters for the sample stations of the cruise AT261 (2022)
    PANGAEA
    Details
    Publication Date: 2023-03-14
    Description: Offshore wind energy is a steadily growing sector contributing to the worldwide energy production. The impact of these offshore constructions on the marine environment, however, remains unclear in many aspects. In fact, little is known about potential emissions from corrosion protection systems such as organic coatings or galvanic anodes composed of Al and Zn alloys, used to protect offshore structures. In order to assess potential chemical emissions from offshore wind farms and their impact on the marine environment water and sediment samples were taken in the surrounding and within different wind farms of the German Bight in April 2018. At every sampling station oceanographic parameters were measured directly on board with respective probes of a multimeter for pH, dissolved oxygen, temperature and conductivity. Additionally, the current associated weather parameters (temperature in air, wind speed, air pressure) were noted from the ship system.
    Keywords: ALTITUDE; AT261; Atair; Atair261; Atair261_10; Atair261_11; Atair261_13; Atair261_14; Atair261_15; Atair261_16; Atair261_17; Atair261_2; Atair261_20; Atair261_21; Atair261_22; Atair261_23; Atair261_24; Atair261_25; Atair261_26; Atair261_27; Atair261_29; Atair261_3; Atair261_30; Atair261_31; Atair261_32; Atair261_33; Atair261_34; Atair261_35; Atair261_36; Atair261_37; Atair261_38; Atair261_39; Atair261_4; Atair261_40; Atair261_41; Atair261_42; Atair261_43; Atair261_44; Atair261_45; Atair261_46; Atair261_47; Atair261_48; Atair261_49; Atair261_50; Atair261_51; Atair261_52; Atair261_53; Atair261_54; Atair261_55; Atair261_56; Atair261_57; Atair261_58; Atair261_59; Atair261_60; Atair261_61; Atair261_62; Atair261_63; Atair261_9; Conductivity; Date/Time of event; DEPTH, water; Elevation of event; Event label; German Bight; Helmholtz-Zentrum Hereon; Hereon; Latitude of event; Longitude of event; MULT; Multimeter; Multiple investigations; Oxygen, dissolved; pH; Pressure, atmospheric; Sample ID; Station_10_HELW3; Station_11_NOST1; Station_13_NOST3; Station_14_NOST4; Station_15_NOST5; Station_16_NOST6; Station_17_NOST7; Station_2_TI7; Station_20_AMWE2; Station_21_AMWE3; Station_22_AMWE4; Station_23_AMWE5; Station_24_AMWE6; Station_25_AMWE7; Station_26_AMWE8; Station_27_AMWE9; Station_29_DOLW1; Station_3_MEWI1; Station_30_DOLW2; Station_31_DOLW3; Station_32_BKRI1; Station_33_BKRI2; Station_34_BKRI3; Station_35_BKRI4; Station_36_BKRI5; Station_37_ALVE2; Station_38_ALVE3; Station_39_ALVE1; Station_4_MEWI3; Station_40_ALVE4; Station_41_DOLW5; Station_42_DOLW6; Station_43_GOWI2; Station_44_GOWI3; Station_45_GOWI5; Station_46_GOWI6; Station_47_GOWI7; Station_48_GOWI8; Station_49_GOWI9; Station_50_GOWI1; Station_51_GOWI4; Station_52_GOWI10; Station_53_GOWI11; Station_54_GOWI20; Station_55_GOWI21; Station_56_GOWI22; Station_57_GOWI23; Station_58_GOWI24; Station_59_GOWI25; Station_60_GOWI26; Station_61_GOWI27; Station_62_GOWI28; Station_63_GOWI29; Station_9_HELW2; Station label; Temperature, air; Temperature, water; Wind speed
    Type: Dataset
    Format: text/tab-separated-values, 581 data points
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 2
    facet.materialart.
    Unknown
    Grain size distribution for sediment samples of the cruise AT261 (2022)
    PANGAEA
    Details
    Publication Date: 2023-02-12
    Description: Offshore wind energy is a steadily growing sector contributing to the worldwide energy production. The impact of these offshore constructions on the marine environment, however, remains unclear in many aspects. In fact, little is known about potential emissions from corrosion protection systems such as organic coatings or galvanic anodes composed of Al and Zn alloys, used to protect offshore structures. In order to assess potential chemical emissions from offshore wind farms and their impact on the marine environment water and sediment samples were taken in the surrounding and within different wind farms of the German Bight in April 2018. The sediment samples were taken by a box grab and analyzed for their grain size distribution by laser diffraction.
    Keywords: AT261; Atair; Atair261; Atair261_10_BC; Atair261_11_BC; Atair261_13_BC; Atair261_14_BC; Atair261_15_BC; Atair261_16_BC; Atair261_17_BC; Atair261_2_BC; Atair261_20_BC; Atair261_21_BC; Atair261_22_BC; Atair261_23_BC; Atair261_24_BC; Atair261_25_BC; Atair261_27_BC; Atair261_29_BC; Atair261_3_BC; Atair261_30_BC; Atair261_31_BC; Atair261_32_BC; Atair261_33_BC; Atair261_34_BC; Atair261_35_BC; Atair261_36_BC; Atair261_37_BC; Atair261_38_BC; Atair261_39_BC; Atair261_4_BC; Atair261_40_BC; Atair261_41_BC; Atair261_42_BC; Atair261_43_BC; Atair261_44_BC; Atair261_46_BC; Atair261_47_BC; Atair261_48_BC; Atair261_49_BC; Atair261_50_BC; Atair261_51_BC; Atair261_52_BC; Atair261_53_BC; Atair261_54_BC; Atair261_55_BC; Atair261_56_BC; Atair261_57_BC; Atair261_58_BC; Atair261_59_BC; Atair261_60_BC; Atair261_61_BC; Atair261_62_BC; Atair261_63_BC; Atair261_9_BC; BC; Box corer; Date/Time of event; DEPTH, sediment/rock; Elevation of event; Event label; German Bight; Helmholtz-Zentrum Hereon; Hereon; Laser diffraction particle size analyser; Latitude of event; Longitude of event; Sample ID; Size fraction 〈 0.020 mm; Size fraction 〈 0.063 mm, mud, silt+clay; Size fraction 〈 0.125 mm; Size fraction 〈 0.250 mm; Station_10_HELW3; Station_11_NOST1; Station_13_NOST3; Station_14_NOST4; Station_15_NOST5; Station_16_NOST6; Station_17_NOST7; Station_2_TI7; Station_20_AMWE2; Station_21_AMWE3; Station_22_AMWE4; Station_23_AMWE5; Station_24_AMWE6; Station_25_AMWE7; Station_27_AMWE9; Station_29_DOLW1; Station_3_MEWI1; Station_30_DOLW2; Station_31_DOLW3; Station_32_BKRI1; Station_33_BKRI2; Station_34_BKRI3; Station_35_BKRI4; Station_36_BKRI5; Station_37_ALVE2; Station_38_ALVE3; Station_39_ALVE1; Station_4_MEWI3; Station_40_ALVE4; Station_41_DOLW5; Station_42_DOLW6; Station_43_GOWI2; Station_44_GOWI3; Station_46_GOWI6; Station_47_GOWI7; Station_48_GOWI8; Station_49_GOWI9; Station_50_GOWI1; Station_51_GOWI4; Station_52_GOWI10; Station_53_GOWI11; Station_54_GOWI20; Station_55_GOWI21; Station_56_GOWI22; Station_57_GOWI23; Station_58_GOWI24; Station_59_GOWI25; Station_60_GOWI26; Station_61_GOWI27; Station_62_GOWI28; Station_63_GOWI29; Station_9_HELW2; Station label
    Type: Dataset
    Format: text/tab-separated-values, 312 data points
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 3
    facet.materialart.
    Unknown
    Metal distribution and Sr and Pb stable isotope ratios for sediment samples of ATAIR cruise AT261 (2023)
    PANGAEA
    Details
    Publication Date: 2023-09-12
    Description: Offshore wind energy is a steadily growing sector contributing to the worldwide energy production. The impact of these offshore constructions on the marine environment, however, remains unclear in many aspects. In fact, little is known about potential emissions from corrosion protection systems such as organic coatings or galvanic anodes composed of Al and Zn alloys, used to protect offshore structures. In order to assess potential chemical emissions from offshore wind farms and their impact on the marine environment water and sediment samples were taken in the surrounding and within different wind farms of the German Bight in April 2018 within the context of the Hereon-BSH project OffChEm. The surface sediment samples were taken by a box grab, homogenized, freeze-dried and wet-sieved to gain the 〈20 µm grain size fraction. The 〈20 µm grain size fraction was acid digested and measured by ICP-MS/MS for their (trace) metal mass fractions. The Sr and Pb isotope ratios were measured by MC ICP-MS after an automated matrix separation with a prepFAST MC system.
    Keywords: Aluminium; Aluminium, limit of detection; Aluminium, limit of quantification; Aluminium, uncertainty; Antimony; Antimony, limit of detection; Antimony, limit of quantification; Antimony, uncertainty; Arsenic; Arsenic, limit of detection; Arsenic, limit of quantification; Arsenic, uncertainty; AT261; Atair; Atair261; Atair261_10_BC; Atair261_11_BC; Atair261_13_BC; Atair261_14_BC; Atair261_15_BC; Atair261_16_BC; Atair261_17_BC; Atair261_2_BC; Atair261_20_BC; Atair261_21_BC; Atair261_22_BC; Atair261_23_BC; Atair261_24_BC; Atair261_25_BC; Atair261_27_BC; Atair261_29_BC; Atair261_3_BC; Atair261_30_BC; Atair261_31_BC; Atair261_32_BC; Atair261_33_BC; Atair261_34_BC; Atair261_35_BC; Atair261_36_BC; Atair261_37_BC; Atair261_38_BC; Atair261_39_BC; Atair261_4_BC; Atair261_40_BC; Atair261_41_BC; Atair261_42_BC; Atair261_43_BC; Atair261_44_BC; Atair261_46_BC; Atair261_47_BC; Atair261_48_BC; Atair261_49_BC; Atair261_50_BC; Atair261_51_BC; Atair261_52_BC; Atair261_53_BC; Atair261_54_BC; Atair261_55_BC; Atair261_56_BC; Atair261_57_BC; Atair261_58_BC; Atair261_59_BC; Atair261_60_BC; Atair261_61_BC; Atair261_62_BC; Atair261_63_BC; Atair261_9_BC; Barium; Barium, limit of detection; Barium, limit of quantification; Barium, uncertainty; BC; Beryllium; Beryllium, limit of detection; Beryllium, limit of quantification; Beryllium, uncertainty; Bismuth; Bismuth, limit of detection; Bismuth, limit of quantification; Bismuth, uncertainty; Box corer; Cadmium; Cadmium, limit of detection; Cadmium, limit of quantification; Cadmium, uncertainty; Caesium; Caesium, limit of detection; Caesium, limit of quantification; Caesium, uncertainty; Calcium; Calcium, limit of detection; Calcium, limit of quantification; Calcium, uncertainty; Cerium; Cerium, limit of detection; Cerium, limit of quantification; Cerium, uncertainty; Chromium; Chromium, limit of detection; Chromium, limit of quantification; Chromium, uncertainty; Cobalt; Cobalt, limit of detection; Cobalt, limit of quantification; Cobalt, uncertainty; DATE/TIME; DEPTH, sediment/rock; Dysprosium; Dysprosium, limit of detection; Dysprosium, limit of quantification; Dysprosium, uncertainty; Element analysis grain size fraction 〈 20 microns via ICP-MS (total digest); ELEVATION; Erbium; Erbium, limit of detection; Erbium, limit of quantification; Erbium, uncertainty; Europium; Europium, limit of detection; Europium, limit of quantification; Europium, uncertainty; Event label; Gadolinium; Gadolinium, limit of detection; Gadolinium, limit of quantification; Gadolinium, uncertainty; Gallium; Gallium, limit of detection; Gallium, limit of quantification; Gallium, uncertainty; German Bight; Helmholtz-Zentrum Hereon; Hereon; Holmium; Holmium, limit of detection; Holmium, limit of quantification; Holmium, uncertainty; Indium; Indium, limit of detection; Indium, limit of quantification; Indium, uncertainty; Iron; Iron, limit of detection; Iron, limit of quantification; Iron, uncertainty; Lanthanum; Lanthanum, limit of detection; Lanthanum, limit of quantification; Lanthanum, uncertainty; LATITUDE; Lead; Lead, limit of detection; Lead, limit of quantification; Lead, uncertainty; Lead-206/Lead-204 ratio; Lead-206/Lead-204 ratio, uncertainty; Lead-207/Lead-204 ratio; Lead-207/Lead-204 ratio, uncertainty; Lead-207/Lead-206, uncertainty; Lead-207/Lead-206 ratio; Lead-208/Lead-204 ratio; Lead-208/Lead-204 ratio, uncertainty; Lead-208/Lead-206 ratio; Lead-208/Lead-206 ratio, uncertainty; Lead-208/Lead-207 ratio; Lead-208/Lead-207 ratio, uncertainty; Lithium; Lithium, limit of detection; Lithium, limit of quantification; Lithium, uncertainty; LONGITUDE; Lutetium; Lutetium, limit of detection; Lutetium, limit of quantification; Lutetium, uncertainty; Magnesium; Magnesium, limit of detection; Magnesium, limit of quantification; Magnesium, uncertainty; Manganese; Manganese, limit of detection; Manganese, limit of quantification; Manganese, uncertainty; Molybdenum; Molybdenum, limit of detection; Molybdenum, limit of quantification; Molybdenum, uncertainty; Multi-collector ICP-MS (MC-ICP-MS), Nu Plasma II, Wrexham, UK; External intra-elemental calibration using NIST SRM 981; Multi-collector ICP-MS (MC-ICP-MS), Nu Plasma II, Wrexham, UK; External intra-elemental calibration using NIST SRM 987; Neodymium; Neodymium, limit of detection; Neodymium, limit of quantification; Neodymium, uncertainty; Nickel; Nickel, limit of detection; Nickel, limit of quantification; Nickel, uncertainty; Potassium; Potassium, limit of detection; Potassium, limit of quantification; Potassium, uncertainty; Praseodymium; Praseodymium, limit of detection; Praseodymium, limit of quantification; Praseodymium, uncertainty; Rubidium; Rubidium, limit of detection; Rubidium, limit of quantification; Rubidium, uncertainty; Samarium; Samarium, limit of detection; Samarium, limit of quantification; Samarium, uncertainty; Sample ID; Sample method; Scandium; Scandium, limit of detection; Scandium, limit of quantification; Scandium, uncertainty; Silver; Silver, limit of detection; Silver, limit of quantification; Silver, uncertainty; Station_10_HELW3; Station_11_NOST1; Station_13_NOST3; Station_14_NOST4; Station_15_NOST5; Station_16_NOST6; Station_17_NOST7; Station_2_TI7; Station_20_AMWE2; Station_21_AMWE3; Station_22_AMWE4; Station_23_AMWE5; Station_24_AMWE6; Station_25_AMWE7; Station_27_AMWE9; Station_29_DOLW1; Station_3_MEWI1; Station_30_DOLW2; Station_31_DOLW3; Station_32_BKRI1; Station_33_BKRI2; Station_34_BKRI3; Station_35_BKRI4; Station_36_BKRI5; Station_37_ALVE2; Station_38_ALVE3; Station_39_ALVE1; Station_4_MEWI3; Station_40_ALVE4; Station_41_DOLW5; Station_42_DOLW6; Station_43_GOWI2; Station_44_GOWI3; Station_46_GOWI6; Station_47_GOWI7; Station_48_GOWI8; Station_49_GOWI9; Station_50_GOWI1; Station_51_GOWI4; Station_52_GOWI10; Station_53_GOWI11; Station_54_GOWI20; Station_55_GOWI21; Station_56_GOWI22; Station_57_GOWI23; Station_58_GOWI24; Station_59_GOWI25; Station_60_GOWI26; Station_61_GOWI27; Station_62_GOWI28; Station_63_GOWI29; Station_9_HELW2; Station label; Strontium; Strontium, limit of detection; Strontium, limit of quantification; Strontium, uncertainty; Strontium-87/Strontium-86 ratio; Strontium-87/Strontium-86 ratio, uncertainty; Terbium; Terbium, limit of detection; Terbium, limit of quantification; Terbium, uncertainty; Thallium; Thallium, limit of detection; Thallium, limit of quantification; Thallium, uncertainty; Thulium; Thulium, limit of detection; Thulium, limit of quantification; Thulium, uncertainty; Titanium; Titanium, limit of detection; Titanium, limit of quantification; Titanium, uncertainty; Tungsten; Tungsten, limit of detection; Tungsten, limit of quantification; Tungsten, uncertainty; Uranium; Uranium, limit of detection; Uranium, limit of quantification; Uranium, uncertainty; Vanadium; Vanadium, limit of detection; Vanadium, limit of quantification; Vanadium, uncertainty; Ytterbium; Ytterbium, limit of detection; Ytterbium, limit of quantification; Ytterbium, uncertainty; Zinc; Zinc, limit of detection; Zinc, limit of quantification; Zinc, uncertainty
    Type: Dataset
    Format: text/tab-separated-values, 9992 data points
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 4
    facet.materialart.
    Unknown
    Metal distribution for sediment samples of the Ludwig Prandtl cruise LP20160725 (2022)
    PANGAEA
    Details
    Publication Date: 2023-08-14
    Description: Offshore wind energy is a steadily growing sector contributing to the worldwide energy production. The impact of these offshore constructions on the marine environment, however, remains unclear in many aspects. In fact, little is known about potential emissions from corrosion protection systems such as organic coatings or galvanic anodes composed of Al and Zn alloys, used to protect offshore structures. In order to assess potential chemical emissions from offshore wind farms and their impact on the marine environment water and sediment samples were taken in the surroundings of offshore wind farms of the German Bight between 25.07.2016 and 02.08.2016. The surface sediment samples were taken by a box grab, homogenized, freeze-dried and wet-sieved to gain the 〈20 µm grain size fraction. The 〈20 µm grain size fraction was acid digested and measured by ICP-MS/MS for their (trace) metal mass fractions.
    Keywords: Arsenic; Arsenic, uncertainty; Barium; Barium, uncertainty; Bismuth; Bismuth, uncertainty; Cadmium; Cadmium, uncertainty; Caesium; Caesium, uncertainty; Calcium; Calcium, uncertainty; Cerium; Cerium, uncertainty; Chromium; Chromium, uncertainty; Cobalt; Cobalt, uncertainty; Date/Time of event; DEPTH, sediment/rock; Dysprosium; Dysprosium, uncertainty; Element analysis grain size fraction 〈 20 microns via ICP-MS (total digest); Erbium; Erbium, uncertainty; Europium; Europium, uncertainty; Event label; Gadolinium; Gadolinium, uncertainty; Gallium; Gallium, uncertainty; Grab; GRAB; Helmholtz-Zentrum Hereon; Hereon; Holmium; Holmium, uncertainty; Indium; Indium, uncertainty; Iron; Iron, uncertainty; Lanthanum; Lanthanum, uncertainty; Latitude of event; Lead; Lead, uncertainty; Lithium; Lithium, uncertainty; Longitude of event; LP20160725; LP20160725_Stat_14_3; LP20160725_Stat_15_1; LP20160725_Stat_16_1; LP20160725_Stat_17_3; LP20160725_Stat_18_1; LP20160725_Stat_19_1; LP20160725_Stat_20_1; LP20160725_Stat_21_1; LP20160725_Stat_22_1; LP20160725_Stat_35_1; LP20160725_Stat_36_1; LP20160725_Stat_37_1; LP20160725_Stat_38_1; LP20160725_Stat_39_1; LP20160725_Stat_40_1; LP20160725_Stat_41_1; LP20160725_Stat_42_1; LP20160725_Stat_43_1; Ludwig Prandtl; Lutetium; Lutetium, uncertainty; Molybdenum; Molybdenum, uncertainty; Neodymium; Neodymium, uncertainty; Nickel; Nickel, uncertainty; North Sea; Phosphorus; Phosphorus, uncertainty; Praseodymium; Praseodymium, uncertainty; Rubidium; Rubidium, uncertainty; S014; S015; S016; S017; S018; S019; S020; S021; S022; S035; S036; S037; S038; S039; S040; S041; S042; S043; Samarium; Samarium, uncertainty; Sample code/label; Scandium; Scandium, uncertainty; Silver; Silver, uncertainty; Sodium; Sodium, uncertainty; Station label; Strontium; Strontium, uncertainty; Terbium; Terbium, uncertainty; Thallium; Thallium, uncertainty; Thorium; Thorium, uncertainty; Thulium; Thulium, uncertainty; Titanium; Titanium, uncertainty; Tungsten; Tungsten, uncertainty; Uranium; Uranium, uncertainty; Vanadium; Vanadium, uncertainty; Ytterbium; Ytterbium, uncertainty; Yttrium; Yttrium, uncertainty; Zinc; Zinc, uncertainty
    Type: Dataset
    Format: text/tab-separated-values, 1584 data points
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 5
    facet.materialart.
    Unknown
    Trace metal distribution for water samples of Ludwig Prandtl cruise LP20160725 (2022)
    PANGAEA
    Details
    Publication Date: 2023-08-14
    Description: Offshore wind energy is a steadily growing sector contributing to the worldwide energy production. The impact of these offshore constructions on the marine environment, however, remains unclear in many aspects. In fact, little is known about potential emissions from corrosion protection systems such as organic coatings or galvanic anodes composed of Al and Zn alloys, used to protect offshore structures. In order to assess potential chemical emissions from offshore wind farms and their impact on the marine environment water and sediment samples were taken in the surroundings of offshore wind farms of the German Bight between 25.07.2016 and 02.08.2016. The water samples were taken with a PFA-coated metal-free water sampler in pre-cleaned LDPE bottles, filtered over 〈0.45 µm polycarbonate filters into pre-cleaned LDPE bottles and acidified with nitric acid. The filtrates were then measured for their (trace) metal concentrations with ICP-MS/MS coupled online to a seaFAST preconcentration and matrix removal system.
    Keywords: Aluminium; Aluminium, standard deviation; Cadmium; Cadmium, standard deviation; Cerium; Cerium, standard deviation; Cobalt; Cobalt, standard deviation; Copper; Copper, standard deviation; Date/Time of event; Dysprosium; Dysprosium, standard deviation; Erbium; Erbium, standard deviation; Europium; Europium, standard deviation; Event label; Gadolinium; Gadolinium, anthropogenic; Gadolinium, anthropogenic, uncertainty; Gadolinium, standard deviation; Gadolinium anomaly; Gadolinium anomaly, uncertainty; Gallium; Gallium, standard deviation; Helmholtz-Zentrum Hereon; Hereon; Holmium; Holmium, standard deviation; ICP-MS, Elemental Scientific, seaFAST; Indium; Indium, standard deviation; Lanthanum; Lanthanum, standard deviation; Latitude of event; Lead; Lead, standard deviation; Longitude of event; LP20160725; LP20160725_Stat_1_2; LP20160725_Stat_10_2; LP20160725_Stat_11_3; LP20160725_Stat_12_3; LP20160725_Stat_13_3; LP20160725_Stat_14_2; LP20160725_Stat_15_3; LP20160725_Stat_16_3; LP20160725_Stat_17_2; LP20160725_Stat_18_3; LP20160725_Stat_19_3; LP20160725_Stat_2_2; LP20160725_Stat_20_3; LP20160725_Stat_21_3; LP20160725_Stat_22_3; LP20160725_Stat_23_2; LP20160725_Stat_24_3; LP20160725_Stat_25_2; LP20160725_Stat_26_3; LP20160725_Stat_27_3; LP20160725_Stat_28_3; LP20160725_Stat_29_3; LP20160725_Stat_3_3; LP20160725_Stat_30_3; LP20160725_Stat_31_3; LP20160725_Stat_32_3; LP20160725_Stat_33_3; LP20160725_Stat_34_3; LP20160725_Stat_35_3; LP20160725_Stat_36_3; LP20160725_Stat_37_3; LP20160725_Stat_38_3; LP20160725_Stat_39_3; LP20160725_Stat_4_2; LP20160725_Stat_40_3; LP20160725_Stat_41_3; LP20160725_Stat_42_3; LP20160725_Stat_43_3; LP20160725_Stat_44_3; LP20160725_Stat_45_3; LP20160725_Stat_46_3; LP20160725_Stat_47_3; LP20160725_Stat_48_3; LP20160725_Stat_49_3; LP20160725_Stat_5_2; LP20160725_Stat_50_3; LP20160725_Stat_51_3; LP20160725_Stat_52_3; LP20160725_Stat_53_3; LP20160725_Stat_54_3; LP20160725_Stat_55_3; LP20160725_Stat_56_2; LP20160725_Stat_57_2; LP20160725_Stat_6_3; LP20160725_Stat_7_3; LP20160725_Stat_8_3; LP20160725_Stat_9_3; Ludwig Prandtl; Lutetium; Lutetium, standard deviation; Manganese; Manganese, standard deviation; Neodymium; Neodymium, standard deviation; Nickel; Nickel, standard deviation; North Sea; Praseodymium; Praseodymium, standard deviation; S001; S002; S003; S004; S005; S006; S007; S008; S009; S010; S011; S012; S013; S014; S015; S016; S017; S018; S019; S020; S021; S022; S023; S024; S025; S026; S027; S028; S029; S030; S031; S032; S033; S034; S035; S036; S037; S038; S039; S040; S041; S042; S043; S044; S045; S046; S047; S048; S049; S050; S051; S052; S053; S054; S055; S056; Samarium; Samarium, standard deviation; Sample code/label; Station label; Terbium; Terbium, standard deviation; Thulium; Thulium, standard deviation; Tungsten; Tungsten, standard deviation; Vanadium; Vanadium, standard deviation; Water sample; WS; Ytterbium; Ytterbium, standard deviation; Yttrium; Yttrium, standard deviation; Zinc; Zinc, standard deviation
    Type: Dataset
    Format: text/tab-separated-values, 3174 data points
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 6
    facet.materialart.
    Unknown
    Seawater and sediment data from offshore wind farms in the German Bight collected during the cruise AT261 (2022)
    PANGAEA
    Details
    Publication Date: 2023-08-14
    Description: Offshore wind energy is a steadily growing sector contributing to the worldwide energy production. The impact of these offshore constructions on the marine environment, however, remains unclear in many aspects. In fact, little is known about potential emissions from corrosion protection systems such as organic coatings or galvanic anodes composed of Al and Zn alloys, used to protect offshore structures. In order to assess potential chemical emissions from offshore wind farms and their impact on the marine environment water and sediment samples were taken in the surrounding and within different wind farms of the German Bight in April 2018.
    Keywords: Helmholtz-Zentrum Hereon; Hereon
    Type: Dataset
    Format: application/zip, 2 datasets
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 7
    facet.materialart.
    Unknown
    Seawater and sediment data from offshore wind farms in the German Bight collected during the cruise AT275 (2022)
    PANGAEA
    Details
    Publication Date: 2024-03-05
    Description: Offshore wind energy is a steadily growing sector contributing to the worldwide energy production. The impact of these offshore constructions on the marine environment, however, remains unclear in many aspects. In fact, little is known about potential emissions from corrosion protection systems such as organic coatings or galvanic anodes composed of Al and Zn alloys, used to protect offshore structures. In order to assess potential chemical emissions from offshore wind farms and their impact on the marine environment water and sediment samples were taken in and around offshore wind farms of the German Bight between 06.03.2019 and 24.03.2019.
    Keywords: Helmholtz-Zentrum Hereon; Hereon
    Type: Dataset
    Format: application/zip, 2 datasets
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 8
    facet.materialart.
    Unknown
    Metal distribution and Sr and Pb stable isotope ratios for sediment samples of Atair cruise AT275 (2023)
    PANGAEA
    Details
    Publication Date: 2024-03-05
    Description: Offshore wind energy is a steadily growing sector contributing to the worldwide energy production. The impact of these offshore constructions on the marine environment, however, remains unclear in many aspects. In fact, little is known about potential emissions from corrosion protection systems such as organic coatings or galvanic anodes composed of Al and Zn alloys, used to protect offshore structures. In order to assess potential chemical emissions from offshore wind farms and their impact on the marine environment water and sediment samples were taken in and around offshore wind farms of the German Bight between 06.03.2019 and 24.03.2019 within the context of the Hereon-BSH project OffChEm. The surface sediment samples were taken by a box grab, homogenized, freeze-dried and wet-sieved to gain the 〈20 µm grain size fraction. The 〈20 µm grain size fraction was acid digested and measured by ICP-MS/MS for their (trace) metal mass fractions. The Sr and Pb isotope ratios were measured by MC ICP-MS after an automated matrix separation with a prepFAST MCTM system.
    Keywords: Aluminium; Aluminium, limit of detection; Aluminium, limit of quantification; Aluminium, uncertainty; Arsenic; Arsenic, limit of detection; Arsenic, limit of quantification; Arsenic, uncertainty; AT275; AT275_Stat_S_097_HELW5; Atair; Atair275; Atair275_11; Atair275_12; Atair275_13; Atair275_14; Atair275_17; Atair275_18; Atair275_19; Atair275_2; Atair275_20; Atair275_21; Atair275_22; Atair275_23; Atair275_24; Atair275_25; Atair275_26; Atair275_27; Atair275_28; Atair275_29; Atair275_30; Atair275_31; Atair275_32; Atair275_33; Atair275_34; Atair275_35; Atair275_36; Atair275_39; Atair275_4; Atair275_40; Atair275_41; Atair275_42; Atair275_43; Atair275_44; Atair275_45; Atair275_46; Atair275_47; Atair275_48; Atair275_49; Atair275_5; Atair275_52; Atair275_53; Atair275_54; Atair275_55; Atair275_56; Atair275_57; Atair275_58; Atair275_60; Atair275_61; Atair275_62; Atair275_64; Atair275_65; Atair275_67; Atair275_68; Atair275_69; Atair275_7; Atair275_70; Atair275_71; Atair275_72; Atair275_73; Atair275_75; Atair275_78; Atair275_79; Atair275_8; Atair275_80; Atair275_81; Atair275_82; Atair275_83; Atair275_84; Atair275_85; Atair275_86; Atair275_87; Atair275_88; Atair275_89; Atair275_9; Atair275_91; Atair275_92; Atair275_93; Atair275_94; Atair275_95; Atair275_96; Atair275_97; Barium; Barium, limit of detection; Barium, limit of quantification; Barium, uncertainty; Beryllium; Beryllium, limit of detection; Beryllium, limit of quantification; Beryllium, uncertainty; Bismuth; Bismuth, limit of detection; Bismuth, limit of quantification; Bismuth, uncertainty; Cadmium; Cadmium, limit of detection; Cadmium, limit of quantification; Cadmium, uncertainty; Caesium; Caesium, limit of detection; Caesium, limit of quantification; Caesium, uncertainty; Calcium; Calcium, limit of detection; Calcium, limit of quantification; Calcium, uncertainty; Cerium; Cerium, limit of detection; Cerium, limit of quantification; Cerium, uncertainty; Chromium; Chromium, limit of detection; Chromium, limit of quantification; Chromium, uncertainty; Cobalt; Cobalt, limit of detection; Cobalt, limit of quantification; Cobalt, uncertainty; DEPTH, sediment/rock; Dysprosium; Dysprosium, limit of detection; Dysprosium, limit of quantification; Dysprosium, uncertainty; Element analysis grain size fraction 〈 20 microns via ICP-MS (total digest); Erbium; Erbium, limit of detection; Erbium, limit of quantification; Erbium, uncertainty; Europium; Europium, limit of detection; Europium, limit of quantification; Europium, uncertainty; Event label; Gadolinium; Gadolinium, limit of detection; Gadolinium, limit of quantification; Gadolinium, uncertainty; Gallium; Gallium, limit of detection; Gallium, limit of quantification; Gallium, uncertainty; Germanium; Germanium, limit of detection; Germanium, limit of quantification; Germanium, uncertainty; Helmholtz-Zentrum Hereon; Hereon; Holmium; Holmium, limit of detection; Holmium, limit of quantification; Holmium, uncertainty; Indium; Indium, limit of detection; Indium, limit of quantification; Indium, uncertainty; International Generic Sample Number; Iron; Iron, limit of detection; Iron, limit of quantification; Iron, uncertainty; Lanthanum; Lanthanum, limit of detection; Lanthanum, limit of quantification; Lanthanum, uncertainty; Lead; Lead, limit of detection; Lead, limit of quantification; Lead, uncertainty; Lead-206/Lead-204 ratio; Lead-206/Lead-204 ratio, uncertainty; Lead-207/Lead-204 ratio; Lead-207/Lead-204 ratio, uncertainty; Lead-207/Lead-206 ratio; Lead-207/Lead-206 ratio, uncertainty; Lead-208/Lead-204 ratio; Lead-208/Lead-204 ratio, uncertainty; Lead-208/Lead-206 ratio; Lead-208/Lead-206 ratio, uncertainty; Lead-208/Lead-207 ratio; Lead-208/Lead-207 ratio, uncertainty; Lithium; Lithium, limit of detection; Lithium, limit of quantification; Lithium, uncertainty; Lutetium; Lutetium, limit of detection; Lutetium, limit of quantification; Lutetium, uncertainty; Magnesium, limit of detection; Magnesium, limit of quantification; Magnesium, uncertainty; Manganese; Manganese, limit of detection; Manganese, limit of quantification; Manganese, uncertainty; Mercury; Mercury, limit of detection; Mercury, limit of quantification; Mercury, uncertainty; Molybdenum; Molybdenum, limit of detection; Molybdenum, limit of quantification; Molybdenum, uncertainty; MULT; Multi-collector ICP-MS (MC-ICP-MS), Nu Plasma II, Wrexham, UK; External intra-elemental calibration using NIST SRM 981; Multi-collector ICP-MS (MC-ICP-MS), Nu Plasma II, Wrexham, UK; External intra-elemental calibration using NIST SRM 987; Multiple investigations; Neodymium; Neodymium, limit of detection; Neodymium, limit of quantification; Neodymium, uncertainty; Nickel; Nickel, limit of detection; Nickel, limit of quantification; Nickel, uncertainty; Niobium; Niobium, limit of detection; Niobium, limit of quantification; Niobium, uncertainty; North Sea; Phosphorus; Phosphorus, limit of detection; Phosphorus, limit of quantification; Phosphorus, uncertainty; Potassium; Potassium, limit of detection; Potassium, limit of quantification; Potassium, uncertainty; Praseodymium; Praseodymium, limit of detection; Praseodymium, limit of quantification; Praseodymium, uncertainty; Rubidium; Rubidium, limit of detection; Rubidium, limit of quantification; Rubidium, uncertainty; S_002_AMWE4; S_004_AMWE3; S_005_AMWE7; S_007_AMWE5; S_008_AMWE6; S_009_AMWE15; S_011_AMWE19; S_012_AMWE20; S_013_AMWE21; S_014_AMWE22; S_017_NOST4; S_018_NOST1; S_019_NOST5; S_020_NOST6; S_021_NOST7; S_022_NOST3; S_023_NOST42; S_024_NOST43; S_025_NOST35; S_026_TI7; S_027_MEWI1; S_028_MEWI3; S_029_MEWI6; S_030_TI13; S_031_MEWI7; S_032_MEWI36; S_033_MEWI37; S_034_MEWI38; S_035_MEWI40; S_036_MEWI41; S_039_DOLW1; S_040_ALVE5; S_041_ALVE4; S_042_ALVE2; S_043_ALVE3; S_044_ALVE1; S_045_BKRI5; S_046_BKRI4; S_047_BKRI3; S_048_BKRI2; S_049_BKRI1; S_052_GOWI10; S_053_GOWI6; S_054_GOWI7; S_055_GOWI9; S_056_GOWI11; S_057_GOWI4; S_058_GOWI3; S_060_GOWI2; S_061_GOWI1; S_062_GOWI8; S_064_GOWI54; S_065_GOWI59; S_067_GOWI26; S_068_GOWI24; S_069_GOWI21; S_070_GOWI25; S_071_GOWI20; S_072_GOWI22; S_073_GOWI23; S_075_GOWI29; S_078_GOWI55; S_079_GOWI57; S_080_DOLW7; S_081_VEJA02; S_082_VEJA03; S_083_VEJA04; S_084_VEJA05; S_085_VEJA06; S_086_VEJA08; S_087_VEJA09; S_088_VEJA10; S_089_VEJA11; S_091_DOLW8; S_092_DOLW10; S_093_DOLW9; S_094_VEJA16; S_095_HELW1; S_096_HELW4; Samarium; Samarium, limit of detection; Samarium, limit of quantification; Samarium, uncertainty; Sample code/label; Sample method; Scandium; Scandium, limit of detection; Scandium, limit of quantification; Scandium, uncertainty; Selenium; Selenium, limit of detection; Selenium, limit of quantification; Selenium, uncertainty; Silver; Silver, limit of detection; Silver, limit of quantification; Silver, uncertainty; Sodium; Sodium, limit of detection; Sodium, limit of quantification; Sodium, uncertainty; Station label; Strontium; Strontium, limit of detection; Strontium, limit of quantification; Strontium, uncertainty; Strontium-87/Strontium-86 ratio; Strontium-87/Strontium-86 ratio, uncertainty; Tantalum; Tantalum, limit of detection; Tantalum, limit of quantification; Tantalum, uncertainty; Tellurium; Tellurium, limit of detection; Tellurium, limit of quantification; Tellurium, uncertainty; Terbium; Terbium, limit of detection; Terbium, limit of quantification; Terbium, uncertainty; Thallium; Thallium, limit of detection; Thallium, limit of quantification; Thallium, uncertainty; Thorium; Thorium, limit of detection; Thorium, limit of quantification; Thorium, uncertainty; Thulium; Thulium, limit of detection; Thulium, limit of quantification; Thulium, uncertainty; Titanium; Titanium, limit of detection; Titanium, limit of quantification; Titanium, uncertainty; Tungsten; Tungsten, limit of detection; Tungsten, limit of quantification; Tungsten, uncertainty; Uranium; Uranium, limit of detection; Uranium, limit of quantification; Uranium, uncertainty; Vanadium; Vanadium, limit of detection; Vanadium, limit
    Type: Dataset
    Format: text/tab-separated-values, 17568 data points
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 9
    facet.materialart.
    Unknown
    Trace metal distribution for water samples of Atair cruise AT275 (2023)
    PANGAEA
    Details
    Publication Date: 2024-03-05
    Description: Offshore wind energy is a steadily growing sector contributing to the worldwide energy production. The impact of these offshore constructions on the marine environment, however, remains unclear in many aspects. In fact, little is known about potential emissions from corrosion protection systems such as organic coatings or galvanic anodes composed of Al and Zn alloys, used to protect offshore structures. In order to assess potential chemical emissions from offshore wind farms and their impact on the marine environment water and sediment samples were taken in and around offshore wind farms of the German Bight between 06.03.2019 and 24.03.2019 within the context of the Hereon-BSH project OffChEm. The water samples were taken in metal-free GO-FLO sampling bottles, filtered over 〈0.45 µm polycarbonate filters into pre-cleaned LDPE bottles and acidified with nitric acid. The filtrates were then measured for their (trace) metal concentrations with ICP-MS/MS coupled online to a seaFAST preconcentration and matrix removal system.
    Keywords: Aluminium; Aluminium, standard deviation; AT275; AT275_Stat_S_097_HELW5; Atair; Atair275; Atair275_11; Atair275_12; Atair275_13; Atair275_14; Atair275_15; Atair275_16; Atair275_17; Atair275_18; Atair275_19; Atair275_2; Atair275_20; Atair275_21; Atair275_22; Atair275_23; Atair275_24; Atair275_25; Atair275_26; Atair275_27; Atair275_28; Atair275_29; Atair275_30; Atair275_31; Atair275_32; Atair275_33; Atair275_34; Atair275_35; Atair275_36; Atair275_39; Atair275_4; Atair275_40; Atair275_41; Atair275_42; Atair275_43; Atair275_44; Atair275_45; Atair275_46; Atair275_47; Atair275_48; Atair275_49; Atair275_5; Atair275_52; Atair275_53; Atair275_54; Atair275_55; Atair275_56; Atair275_57; Atair275_58; Atair275_6; Atair275_60; Atair275_61; Atair275_64; Atair275_65; Atair275_67; Atair275_68; Atair275_69; Atair275_7; Atair275_70; Atair275_71; Atair275_72; Atair275_73; Atair275_75; Atair275_78; Atair275_79; Atair275_8; Atair275_80; Atair275_81; Atair275_82; Atair275_83; Atair275_84; Atair275_85; Atair275_86; Atair275_87; Atair275_88; Atair275_89; Atair275_9; Atair275_90; Atair275_91; Atair275_92; Atair275_93; Atair275_94; Atair275_95; Atair275_96; Atair275_97; Cadmium; Cadmium, standard deviation; Cerium; Cerium, standard deviation; Cobalt; Cobalt, standard deviation; Copper; Copper, standard deviation; Date/Time of event; DEPTH, water; Dysprosium; Dysprosium, standard deviation; Elevation of event; Erbium; Erbium, standard deviation; Europium; Europium, standard deviation; Event label; Gadolinium; Gadolinium, anthropogenic; Gadolinium, anthropogenic, uncertainty; Gadolinium, standard deviation; Gadolinium anomaly; Gadolinium anomaly, uncertainty; Gallium; Gallium, standard deviation; Helmholtz-Zentrum Hereon; Hereon; Holmium; Holmium, standard deviation; ICP-MS, Elemental Scientific, seaFAST; Indium; Indium, standard deviation; International Generic Sample Number; Iron; Iron, standard deviation; Lanthanum; Lanthanum, standard deviation; Latitude of event; Lead; Lead, standard deviation; Longitude of event; Lutetium; Lutetium, standard deviation; Manganese; Manganese, standard deviation; Molybdenum; Molybdenum, standard deviation; MULT; Multiple investigations; Neodymium; Neodymium, standard deviation; Nickel; Nickel, standard deviation; North Sea; Praseodymium; Praseodymium, standard deviation; Quality assessment; S_002_AMWE4; S_004_AMWE3; S_005_AMWE7; S_006_ANWE8; S_007_AMWE5; S_008_AMWE6; S_009_AMWE15; S_011_AMWE19; S_012_AMWE20; S_013_AMWE21; S_014_AMWE22; S_015_NOST4_WH; S_016_HELW1_WH; S_017_NOST4; S_018_NOST1; S_019_NOST5; S_020_NOST6; S_021_NOST7; S_022_NOST3; S_023_NOST42; S_024_NOST43; S_025_NOST35; S_026_TI7; S_027_MEWI1; S_028_MEWI3; S_029_MEWI6; S_030_TI13; S_031_MEWI7; S_032_MEWI36; S_033_MEWI37; S_034_MEWI38; S_035_MEWI40; S_036_MEWI41; S_039_DOLW1; S_040_ALVE5; S_041_ALVE4; S_042_ALVE2; S_043_ALVE3; S_044_ALVE1; S_045_BKRI5; S_046_BKRI4; S_047_BKRI3; S_048_BKRI2; S_049_BKRI1; S_052_GOWI10; S_053_GOWI6; S_054_GOWI7; S_055_GOWI9; S_056_GOWI11; S_057_GOWI4; S_058_GOWI3; S_060_GOWI2; S_061_GOWI1; S_064_GOWI54; S_065_GOWI59; S_067_GOWI26; S_068_GOWI24; S_069_GOWI21; S_070_GOWI25; S_071_GOWI20; S_072_GOWI22; S_073_GOWI23; S_075_GOWI29; S_078_GOWI55; S_079_GOWI57; S_080_DOLW7; S_081_VEJA02; S_082_VEJA03; S_083_VEJA04; S_084_VEJA05; S_085_VEJA06; S_086_VEJA08; S_087_VEJA09; S_088_VEJA10; S_089_VEJA11; S_090_VEJA12; S_091_DOLW8; S_092_DOLW10; S_093_DOLW9; S_094_VEJA16; S_095_HELW1; S_096_HELW4; Samarium; Samarium, standard deviation; Sample code/label; Station label; Terbium; Terbium, standard deviation; Thulium; Thulium, standard deviation; Tin; Tungsten; Tungsten, standard deviation; Uranium; Uranium, standard deviation; Vanadium; Vanadium, standard deviation; Ytterbium; Ytterbium, standard deviation; Yttrium; Yttrium, standard deviation; Zinc; Zinc, standard deviation
    Type: Dataset
    Format: text/tab-separated-values, 5499 data points
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 10
    facet.materialart.
    Unknown
    Seawater and sediment data from offshore wind farms in the German Bight collected during the cruise AT275 (2022)
    PANGAEA
    Details
    Publication Date: 2024-03-05
    Description: Offshore wind energy is a steadily growing sector contributing to the worldwide energy production. The impact of these offshore constructions on the marine environment, however, remains unclear in many aspects. In fact, little is known about potential emissions from corrosion protection systems such as organic coatings or galvanic anodes composed of Al and Zn alloys, used to protect offshore structures. In order to assess potential chemical emissions from offshore wind farms and their impact on the marine environment water and sediment samples were taken in and around offshore wind farms of the German Bight between 06.03.2019 and 24.03.2019.
    Keywords: ALTITUDE; AT275; AT275_Stat_S_097_HELW5; Atair; Atair275; Atair275_11; Atair275_12; Atair275_13; Atair275_14; Atair275_15; Atair275_16; Atair275_17; Atair275_18; Atair275_19; Atair275_2; Atair275_20; Atair275_21; Atair275_22; Atair275_23; Atair275_24; Atair275_25; Atair275_26; Atair275_27; Atair275_28; Atair275_29; Atair275_30; Atair275_31; Atair275_32; Atair275_33; Atair275_34; Atair275_35; Atair275_36; Atair275_39; Atair275_4; Atair275_40; Atair275_41; Atair275_42; Atair275_43; Atair275_44; Atair275_45; Atair275_46; Atair275_47; Atair275_48; Atair275_49; Atair275_5; Atair275_52; Atair275_53; Atair275_54; Atair275_55; Atair275_56; Atair275_57; Atair275_58; Atair275_6; Atair275_60; Atair275_61; Atair275_62; Atair275_64; Atair275_65; Atair275_67; Atair275_68; Atair275_69; Atair275_7; Atair275_70; Atair275_71; Atair275_72; Atair275_73; Atair275_75; Atair275_78; Atair275_79; Atair275_8; Atair275_80; Atair275_81; Atair275_82; Atair275_83; Atair275_84; Atair275_85; Atair275_86; Atair275_87; Atair275_88; Atair275_89; Atair275_9; Atair275_90; Atair275_91; Atair275_92; Atair275_93; Atair275_94; Atair275_95; Atair275_96; Atair275_97; Conductivity; Date/Time of event; DEPTH, water; Elevation of event; Event label; Helmholtz-Zentrum Hereon; Hereon; Latitude of event; Longitude of event; MULT; Multimeter; Multiple investigations; North Sea; Oxygen, dissolved; pH; Pressure, atmospheric; S_002_AMWE4; S_004_AMWE3; S_005_AMWE7; S_006_ANWE8; S_007_AMWE5; S_008_AMWE6; S_009_AMWE15; S_011_AMWE19; S_012_AMWE20; S_013_AMWE21; S_014_AMWE22; S_015_NOST4_WH; S_016_HELW1_WH; S_017_NOST4; S_018_NOST1; S_019_NOST5; S_020_NOST6; S_021_NOST7; S_022_NOST3; S_023_NOST42; S_024_NOST43; S_025_NOST35; S_026_TI7; S_027_MEWI1; S_028_MEWI3; S_029_MEWI6; S_030_TI13; S_031_MEWI7; S_032_MEWI36; S_033_MEWI37; S_034_MEWI38; S_035_MEWI40; S_036_MEWI41; S_039_DOLW1; S_040_ALVE5; S_041_ALVE4; S_042_ALVE2; S_043_ALVE3; S_044_ALVE1; S_045_BKRI5; S_046_BKRI4; S_047_BKRI3; S_048_BKRI2; S_049_BKRI1; S_052_GOWI10; S_053_GOWI6; S_054_GOWI7; S_055_GOWI9; S_056_GOWI11; S_057_GOWI4; S_058_GOWI3; S_060_GOWI2; S_061_GOWI1; S_062_GOWI8; S_064_GOWI54; S_065_GOWI59; S_067_GOWI26; S_068_GOWI24; S_069_GOWI21; S_070_GOWI25; S_071_GOWI20; S_072_GOWI22; S_073_GOWI23; S_075_GOWI29; S_078_GOWI55; S_079_GOWI57; S_080_DOLW7; S_081_VEJA02; S_082_VEJA03; S_083_VEJA04; S_084_VEJA05; S_085_VEJA06; S_086_VEJA08; S_087_VEJA09; S_088_VEJA10; S_089_VEJA11; S_090_VEJA12; S_091_DOLW8; S_092_DOLW10; S_093_DOLW9; S_094_VEJA16; S_095_HELW1; S_096_HELW4; Sample ID; Station label; Temperature, air; Temperature, water; Wind speed
    Type: Dataset
    Format: text/tab-separated-values, 908 data points
    Location Call Number Expected Availability
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    DATA PANGAEA
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