_version_ 1867168230872711168
author Nomura, Daiki
Akino, Ryota
Webb, Alison L
Li, Yuhong
Dall'Osto, Manuel
Schmidt, Katrin
Droste, Elise Sayana
Chamberlain, Emelia
Kolabutin, Nikolai
Shimanchuk, Egor
Dadic, Ruzica
Fong, Allison A
Torres-Valdés, Sinhué
Heitmann, Laura
Ludwichowski, Kai-Uwe
Hoppe, Clara Jule Marie
Whitmore, Laura M
Meyer, Hanno
Mellat, Moein
Marent, Andreas
Werner, Martin
Inoue, Jun
Delille, Bruno
author_facet Nomura, Daiki
Akino, Ryota
Webb, Alison L
Li, Yuhong
Dall'Osto, Manuel
Schmidt, Katrin
Droste, Elise Sayana
Chamberlain, Emelia
Kolabutin, Nikolai
Shimanchuk, Egor
Dadic, Ruzica
Fong, Allison A
Torres-Valdés, Sinhué
Heitmann, Laura
Ludwichowski, Kai-Uwe
Hoppe, Clara Jule Marie
Whitmore, Laura M
Meyer, Hanno
Mellat, Moein
Marent, Andreas
Werner, Martin
Inoue, Jun
Delille, Bruno
collection Datos científicos de ciencias marinas y ambientales
contents Nutrient concentrations (NO3−, NO2−, NH4+, PO43−, and Si(OH)4), water oxygen isotope compositions (δ18O), and salinity were measured for ice samples from melt pond, and water from melt pond and lead during MOSAiC Leg 5 (August and September 2020). Ice cores for the melt pond bottom ice and melt pond surface ice were collected using an ice corer (Mark II coring system, Kovacs Enterprises, Inc., Indianapolis, USA). Also, we sampled small pieces of the pond bottom ice dislodged and floated to the surface of the melt pond by poking with a ruler. After sampling ice samples, we immediately drilled holes on ice and measured ice temperatures with a needle-type temperature sensor (Testo 110 NTC, Brandt Instruments, Inc., USA). Ice cores were segmented at 10-cm intervals. Dislodged ice was cut into 0.25 m×0.25 m size. All ice samples were placed into ice melting bags (Smart bags PA, AAK 5L, GL Sciences Inc., Japan) and melted in the dark at +4°C. For the discrete water sampling from the melt ponds and leads, first, we checked the vertical structure and depth of the meltwater layer from the same hole used for the RINKO Profiler (ASTD152, JFE Advantech, Japan) by attaching a conductivity sensor (Cond 315i, WTW GmbH, Germany) to a 2-m-long ruler and inserting the ruler into the lead water until the salinity measured with the Cond 315i increased at the meltwater–seawater interface. Water was pumped up with a peristaltic pump through a 2-m-long PTFE tube (L/S Pump Tubing, Masterflex, USA) at depths corresponding to meltwater (surface), the interface between meltwater and seawater (interface), and seawater (bottom). Salinity was measured at each depth by attaching a Cond 315i conductivity sensor to the bottom of the ruler. The tube intake was likewise attached to the bottom of the ruler. Ice melt water and water samples from melt pond and lead were subsampled into a 30-mL glass, screw-cap vials for later δ18O analysis, a 100-mL polypropylene bottles for salinity, and into 50-mL polyethylene screw-cap vials (Thermo Fisher Scientific Inc., Waltham, MA, USA) for later measurement of nutrient concentrations, after filtration through a 0.22-μm Durapore polyvinylidene fluoride membrane filter (MILLEX GV Filter unit, Merck Millipore Ltd., Germany). Samples for δ18O were stored at room temperature (+20°C). Salinity was measured with the same conductivity sensor used for the sea ice (Cond 315i, WTW GmbH, Germany). The samples for nutrient measurements were stored in a freezer (–20°C) before analysis. Oxygen isotope analyses were carried out with a mass spectrometer (DELTA-S Finnigan MAT, USA) at the ISOLAB Facility at AWI Potsdam by the equilibration method (details in Meyer et al., 2000; 2022). Nutrient samples were analyzed at the AWI Nutrient Facility between January and March 2021 using a Seal Analytical AA3 continuous flow auto-analyzer, controlled by AACE software version 7.09. Best-practice procedures for the measurement of nutrients were adopted following GO-SHIP recommendations (Becker et al., 2019; Hydes et al., 2010).
format Dataset Open Access
id pangaea_https___doi_org_10_1594_PANGAEA_972728
institution PANGAEA
language en
publishDate 2024
publisher PANGAEA
record_format pangaea
spellingShingle Melt pond ice sampling for nutrients, oxygen isotope compositions, and salinity during expedition PS122/5 (MOSAiC Leg 5) to the Central Arctic in August-September 2020
Nomura, Daiki
Akino, Ryota
Webb, Alison L
Li, Yuhong
Dall'Osto, Manuel
Schmidt, Katrin
Droste, Elise Sayana
Chamberlain, Emelia
Kolabutin, Nikolai
Shimanchuk, Egor
Dadic, Ruzica
Fong, Allison A
Torres-Valdés, Sinhué
Heitmann, Laura
Ludwichowski, Kai-Uwe
Hoppe, Clara Jule Marie
Whitmore, Laura M
Meyer, Hanno
Mellat, Moein
Marent, Andreas
Werner, Martin
Inoue, Jun
Delille, Bruno
Ammonium; Arctic Ocean; Conductivity sensor Cond 315i, WTW GmbH, Germany; Continuous flow analyser, Seal, AA3; DATE/TIME; DEPTH, water; Event label; IC; Ice corer; LATITUDE; leads; LONGITUDE; Mass spectrometer Finnigan MAT Delta-S (ISOLAB); melt ponds; MOSAiC; MOSAiC20192020; Multidisciplinary drifting Observatory for the Study of Arctic Climate; Needle-type temperature sensor, Brandt Instruments, Testo 110 NTC; Nitrate and Nitrite; Nitrite; nutrients; Phosphate; Polarstern; PS122/5; PS122/5_59-343; PS122/5_59-344; PS122/5_61-206; PS122/5_62-117; PS122/5_62-120; PS122/5_62-35; PS122/5_62-40; PS122/5_62-5; Salinity; Sample type; Silicate; Station label; Temperature, water; Water sample; WS; δ18O, water
Nutrient concentrations (NO3−, NO2−, NH4+, PO43−, and Si(OH)4), water oxygen isotope compositions (δ18O), and salinity were measured for ice samples from melt pond, and water from melt pond and lead during MOSAiC Leg 5 (August and September 2020). Ice cores for the melt pond bottom ice and melt pond surface ice were collected using an ice corer (Mark II coring system, Kovacs Enterprises, Inc., Indianapolis, USA). Also, we sampled small pieces of the pond bottom ice dislodged and floated to the surface of the melt pond by poking with a ruler. After sampling ice samples, we immediately drilled holes on ice and measured ice temperatures with a needle-type temperature sensor (Testo 110 NTC, Brandt Instruments, Inc., USA). Ice cores were segmented at 10-cm intervals. Dislodged ice was cut into 0.25 m×0.25 m size. All ice samples were placed into ice melting bags (Smart bags PA, AAK 5L, GL Sciences Inc., Japan) and melted in the dark at +4°C. For the discrete water sampling from the melt ponds and leads, first, we checked the vertical structure and depth of the meltwater layer from the same hole used for the RINKO Profiler (ASTD152, JFE Advantech, Japan) by attaching a conductivity sensor (Cond 315i, WTW GmbH, Germany) to a 2-m-long ruler and inserting the ruler into the lead water until the salinity measured with the Cond 315i increased at the meltwater–seawater interface. Water was pumped up with a peristaltic pump through a 2-m-long PTFE tube (L/S Pump Tubing, Masterflex, USA) at depths corresponding to meltwater (surface), the interface between meltwater and seawater (interface), and seawater (bottom). Salinity was measured at each depth by attaching a Cond 315i conductivity sensor to the bottom of the ruler. The tube intake was likewise attached to the bottom of the ruler. Ice melt water and water samples from melt pond and lead were subsampled into a 30-mL glass, screw-cap vials for later δ18O analysis, a 100-mL polypropylene bottles for salinity, and into 50-mL polyethylene screw-cap vials (Thermo Fisher Scientific Inc., Waltham, MA, USA) for later measurement of nutrient concentrations, after filtration through a 0.22-μm Durapore polyvinylidene fluoride membrane filter (MILLEX GV Filter unit, Merck Millipore Ltd., Germany). Samples for δ18O were stored at room temperature (+20°C). Salinity was measured with the same conductivity sensor used for the sea ice (Cond 315i, WTW GmbH, Germany). The samples for nutrient measurements were stored in a freezer (–20°C) before analysis. Oxygen isotope analyses were carried out with a mass spectrometer (DELTA-S Finnigan MAT, USA) at the ISOLAB Facility at AWI Potsdam by the equilibration method (details in Meyer et al., 2000; 2022). Nutrient samples were analyzed at the AWI Nutrient Facility between January and March 2021 using a Seal Analytical AA3 continuous flow auto-analyzer, controlled by AACE software version 7.09. Best-practice procedures for the measurement of nutrients were adopted following GO-SHIP recommendations (Becker et al., 2019; Hydes et al., 2010).
title Melt pond ice sampling for nutrients, oxygen isotope compositions, and salinity during expedition PS122/5 (MOSAiC Leg 5) to the Central Arctic in August-September 2020
topic Ammonium; Arctic Ocean; Conductivity sensor Cond 315i, WTW GmbH, Germany; Continuous flow analyser, Seal, AA3; DATE/TIME; DEPTH, water; Event label; IC; Ice corer; LATITUDE; leads; LONGITUDE; Mass spectrometer Finnigan MAT Delta-S (ISOLAB); melt ponds; MOSAiC; MOSAiC20192020; Multidisciplinary drifting Observatory for the Study of Arctic Climate; Needle-type temperature sensor, Brandt Instruments, Testo 110 NTC; Nitrate and Nitrite; Nitrite; nutrients; Phosphate; Polarstern; PS122/5; PS122/5_59-343; PS122/5_59-344; PS122/5_61-206; PS122/5_62-117; PS122/5_62-120; PS122/5_62-35; PS122/5_62-40; PS122/5_62-5; Salinity; Sample type; Silicate; Station label; Temperature, water; Water sample; WS; δ18O, water
url https://doi.org/10.1594/PANGAEA.972728