Elevated sources of cobalt in the Arctic Ocean

Cobalt (Co) is an important bioactive trace metal that can limit or co-limit phytoplankton growth in many regions of the ocean. Total dissolved and labile Co measurements in the Canadian sector of the Arctic Ocean during U.S. GEOTRACES Arctic expedition (GN01) and the Canadian International Polar Ye...

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Main Authors: Bundy, Randelle M., Tagliabue, Alessandro, Hawco, Nicholas J., Morton, Peter L., Twining, Benjamin S., Hatta, Mariko, Noble, Abigail, Cape, Mattias R., John, Seth G., Cullen, Jay T., Saito, Mak A.
Format: Text
Language:English
Published: 2020
Subjects:
Ice
Online Access:https://doi.org/10.5194/bg-2020-84
https://www.biogeosciences-discuss.net/bg-2020-84/
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spelling ftcopernicus:oai:publications.copernicus.org:bgd84388 2023-05-15T14:29:22+02:00 Elevated sources of cobalt in the Arctic Ocean Bundy, Randelle M. Tagliabue, Alessandro Hawco, Nicholas J. Morton, Peter L. Twining, Benjamin S. Hatta, Mariko Noble, Abigail Cape, Mattias R. John, Seth G. Cullen, Jay T. Saito, Mak A. 2020-04-09 application/pdf https://doi.org/10.5194/bg-2020-84 https://www.biogeosciences-discuss.net/bg-2020-84/ eng eng doi:10.5194/bg-2020-84 https://www.biogeosciences-discuss.net/bg-2020-84/ eISSN: 1726-4189 Text 2020 ftcopernicus https://doi.org/10.5194/bg-2020-84 2020-04-13T14:41:59Z Cobalt (Co) is an important bioactive trace metal that can limit or co-limit phytoplankton growth in many regions of the ocean. Total dissolved and labile Co measurements in the Canadian sector of the Arctic Ocean during U.S. GEOTRACES Arctic expedition (GN01) and the Canadian International Polar Year-GEOTRACES expedition (GIPY14) revealed a dynamic biogeochemical cycle for Co in this basin. The major sources of Co in the Arctic were from shelf regions and rivers, with only minimal contributions from other freshwater sources (sea ice, snow) and aeolian deposition. The most striking feature was the extremely high concentrations of dissolved Co in the upper 100 m, with concentrations routinely exceeding 800 pmol L −1 over the shelf regions. This plume of high Co persisted throughout the Arctic basin and extended to the North Pole, where sources of Co shifted from primarily shelf-derived to riverine, as freshwater from Arctic rivers was entrained in the Transpolar Drift. Dissolved Co was also strongly organically-complexed in the Arctic, ranging from 70–100 % complexed in the surface and deep ocean, respectively. Deep water concentrations of dissolved Co were remarkably consistent throughout the basin (~ 55 pmol L −1 ), with concentrations reflecting those of deep Atlantic water and deep ocean scavenging of dissolved Co. A biogeochemical model of Co cycling was used to support the hypothesis that the majority of the high surface Co in the Arctic was emanating from the shelf. The model showed that the high concentrations of Co observed along the transect were due to the large shelf area of the Arctic, as well as dampened scavenging of Co by manganese (Mn)-oxidizing bacteria due to the lower temperatures. The majority of this scavenging appears to have occurred in the upper 200 m, with minimal additional scavenging below this depth. Preliminary evidence suggests that both dissolved and labile Co are increasing over time on the Arctic shelf, and the elevated surface concentrations of Co likely leads to a net flux of Co out of the Arctic, with implications for downstream biological uptake of Co in the North Atlantic and elevated Co in North Atlantic Deep Water. Understanding the current distributions of Co in the Arctic will be important for constraining changes to Co inputs resulting from regional intensification of freshwater fluxes from ice and permafrost melt in response to ongoing climate change. Text Arctic Basin Arctic Arctic Ocean Climate change Ice International Polar Year North Atlantic Deep Water North Atlantic North Pole permafrost Phytoplankton Sea ice Copernicus Publications: E-Journals Arctic Arctic Ocean North Pole
institution Open Polar
collection Copernicus Publications: E-Journals
op_collection_id ftcopernicus
language English
description Cobalt (Co) is an important bioactive trace metal that can limit or co-limit phytoplankton growth in many regions of the ocean. Total dissolved and labile Co measurements in the Canadian sector of the Arctic Ocean during U.S. GEOTRACES Arctic expedition (GN01) and the Canadian International Polar Year-GEOTRACES expedition (GIPY14) revealed a dynamic biogeochemical cycle for Co in this basin. The major sources of Co in the Arctic were from shelf regions and rivers, with only minimal contributions from other freshwater sources (sea ice, snow) and aeolian deposition. The most striking feature was the extremely high concentrations of dissolved Co in the upper 100 m, with concentrations routinely exceeding 800 pmol L −1 over the shelf regions. This plume of high Co persisted throughout the Arctic basin and extended to the North Pole, where sources of Co shifted from primarily shelf-derived to riverine, as freshwater from Arctic rivers was entrained in the Transpolar Drift. Dissolved Co was also strongly organically-complexed in the Arctic, ranging from 70–100 % complexed in the surface and deep ocean, respectively. Deep water concentrations of dissolved Co were remarkably consistent throughout the basin (~ 55 pmol L −1 ), with concentrations reflecting those of deep Atlantic water and deep ocean scavenging of dissolved Co. A biogeochemical model of Co cycling was used to support the hypothesis that the majority of the high surface Co in the Arctic was emanating from the shelf. The model showed that the high concentrations of Co observed along the transect were due to the large shelf area of the Arctic, as well as dampened scavenging of Co by manganese (Mn)-oxidizing bacteria due to the lower temperatures. The majority of this scavenging appears to have occurred in the upper 200 m, with minimal additional scavenging below this depth. Preliminary evidence suggests that both dissolved and labile Co are increasing over time on the Arctic shelf, and the elevated surface concentrations of Co likely leads to a net flux of Co out of the Arctic, with implications for downstream biological uptake of Co in the North Atlantic and elevated Co in North Atlantic Deep Water. Understanding the current distributions of Co in the Arctic will be important for constraining changes to Co inputs resulting from regional intensification of freshwater fluxes from ice and permafrost melt in response to ongoing climate change.
format Text
author Bundy, Randelle M.
Tagliabue, Alessandro
Hawco, Nicholas J.
Morton, Peter L.
Twining, Benjamin S.
Hatta, Mariko
Noble, Abigail
Cape, Mattias R.
John, Seth G.
Cullen, Jay T.
Saito, Mak A.
spellingShingle Bundy, Randelle M.
Tagliabue, Alessandro
Hawco, Nicholas J.
Morton, Peter L.
Twining, Benjamin S.
Hatta, Mariko
Noble, Abigail
Cape, Mattias R.
John, Seth G.
Cullen, Jay T.
Saito, Mak A.
Elevated sources of cobalt in the Arctic Ocean
author_facet Bundy, Randelle M.
Tagliabue, Alessandro
Hawco, Nicholas J.
Morton, Peter L.
Twining, Benjamin S.
Hatta, Mariko
Noble, Abigail
Cape, Mattias R.
John, Seth G.
Cullen, Jay T.
Saito, Mak A.
author_sort Bundy, Randelle M.
title Elevated sources of cobalt in the Arctic Ocean
title_short Elevated sources of cobalt in the Arctic Ocean
title_full Elevated sources of cobalt in the Arctic Ocean
title_fullStr Elevated sources of cobalt in the Arctic Ocean
title_full_unstemmed Elevated sources of cobalt in the Arctic Ocean
title_sort elevated sources of cobalt in the arctic ocean
publishDate 2020
url https://doi.org/10.5194/bg-2020-84
https://www.biogeosciences-discuss.net/bg-2020-84/
geographic Arctic
Arctic Ocean
North Pole
geographic_facet Arctic
Arctic Ocean
North Pole
genre Arctic Basin
Arctic
Arctic Ocean
Climate change
Ice
International Polar Year
North Atlantic Deep Water
North Atlantic
North Pole
permafrost
Phytoplankton
Sea ice
genre_facet Arctic Basin
Arctic
Arctic Ocean
Climate change
Ice
International Polar Year
North Atlantic Deep Water
North Atlantic
North Pole
permafrost
Phytoplankton
Sea ice
op_source eISSN: 1726-4189
op_relation doi:10.5194/bg-2020-84
https://www.biogeosciences-discuss.net/bg-2020-84/
op_doi https://doi.org/10.5194/bg-2020-84
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