Nitrate Supply Routes and Impact of Internal Cycling in the North Atlantic Ocean Inferred From Nitrate Isotopic Composition

Florian Deman; Debany Fonseca-Batista; Arnout Roukaerts; M. Garcia-Ibanez; Emilie Le Roy; E.P.D.N. Thilakarathne; Marc Elskens; Frank Dehairs; François Fripiat

doi:10.1029/2020GB006887

Nitrate Supply Routes and Impact of Internal Cycling in the North Atlantic Ocean Inferred From Nitrate Isotopic Composition

Florian Deman, Debany Fonseca-Batista, Arnout Roukaerts, M. Garcia-Ibanez, Emilie Le Roy, E.P.D.N. Thilakarathne, Marc Elskens, Frank Dehairs, François Fripiat

Research output: Contribution to journal › Article › peer-review

10 Citations (Scopus)

Abstract

In this study we report full-depth water column profiles for nitrogen and oxygen isotopic composition (δ15N and δ18O) of nitrate (NO3) during the GEOTRACES GA01 cruise (2014). This transect intersects the double gyre system of the subtropical and subpolar regions of the North Atlantic separated by a strong transition zone, the North Atlantic Current. The distribution of NO3 δ15N and δ18O shows that assimilation by phytoplankton is the main process controlling the NO3 isotopic composition in the upper 150m, with values increasing in a NO3 δ18O versus δ15N space along a line with a slope of one toward the
surface. In the subpolar gyre, a single relationship between the degree of NO3 consumption and residual NO3 δ15N supports the view that NO3 is supplied via Ekman upwelling and deep winter convection, and progressively consumed during the Ekman transport of surface water southward. The co-occurrence of
partial NO3 assimilation and nitrification in the deep mixed layer of the subpolar gyre elevates subsurface NO3 δ18O in comparison to deep oceanic values. This signal propagates through isopycnal exchanges to greater depths at lower latitudes. With recirculation in the subtropical gyre, cycles of quantitative
consumption-nitrification progressively decrease subsurface NO3 δ18O toward the δ18O of regenerated NO3. The low NO3 δ15N observed south of the Subarctic Front is mostly explained by N2 fixation, although a contribution from the Mediterranean outflow is required to explain the lower NO3 δ15N signal
observed between 600 and 1500 m depth close to the Iberian margin.

Original language	English
Article number	e2020GB006887
Journal	Global Biogeochemical Cycles
Volume	35
Issue number	4
DOIs	https://doi.org/10.1029/2020GB006887
Publication status	Published - Apr 2021

Bibliographical note

Funding Information:
The authors thank the captain and crew of the R/V for organizing the logistics on board as well as chief scientists G. Sarthou and P. Lherminier for their assistance and support during the GEOVIDE expedition. P. Lherminier, P. Tréguer, F. Pérez and C. Schmechtig are acknowledged for providing CTD and nutrients concentration data. The GEOVIDE project was co‐funded by the French national program LEFE/INSU (GEOVIDE), ANR Blanc (GEOVIDE) and RPDOC, LabEX MER and IFREMER. F. Deman was supported by the Belgian Federal Science Policy Office (Belspo contract BL/12/C63) while writing the manuscript. This work was financed by Flanders Research Foundation (FWO contract G0715.12N) and Vrije Universiteit Brussel, R&D, Strategic Research Plan “Tracers of Past & Present Global Changes”. During the preparation of the manuscript, Debany Fonseca‐Batista was supported by funding from the Canada First Research Excellence Fund, through an International Postdoctoral Fellowship of the Ocean Frontier Institute (OFI) at Dalhousie University. Pourquoi Pas?

Funding Information:
The authors thank the captain and crew of the R/V Pourquoi Pas? for organizing the logistics on board as well as chief scientists G. Sarthou and P. Lherminier for their assistance and support during the GEOVIDE expedition. P. Lherminier, P. Tréguer, F. Pérez and C. Schmechtig are acknowledged for providing CTD and nutrients concentration data. The GEOVIDE project was co-funded by the French national program LEFE/INSU (GEOVIDE), ANR Blanc (GEOVIDE) and RPDOC, LabEX MER and IFREMER. F. Deman was supported by the Belgian Federal Science Policy Office (Belspo contract BL/12/C63) while writing the manuscript. This work was financed by Flanders Research Foundation (FWO contract G0715.12N) and Vrije Universiteit Brussel, R&D, Strategic Research Plan “Tracers of Past & Present Global Changes”. During the preparation of the manuscript, Debany Fonseca-Batista was supported by funding from the Canada First Research Excellence Fund, through an International Postdoctoral Fellowship of the Ocean Frontier Institute (OFI) at Dalhousie University.

Publisher Copyright:
© 2021. American Geophysical Union. All Rights Reserved.

Copyright:
Copyright 2021 Elsevier B.V., All rights reserved.

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10.1029/2020GB006887

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Deman, F., Fonseca-Batista, D., Roukaerts, A., Garcia-Ibanez, M., Le Roy, E., Thilakarathne, E. P. D. N., Elskens, M., Dehairs, F., & Fripiat, F. (2021). Nitrate Supply Routes and Impact of Internal Cycling in the North Atlantic Ocean Inferred From Nitrate Isotopic Composition. Global Biogeochemical Cycles, 35(4), Article e2020GB006887. https://doi.org/10.1029/2020GB006887

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title = "Nitrate Supply Routes and Impact of Internal Cycling in the North Atlantic Ocean Inferred From Nitrate Isotopic Composition",

abstract = "In this study we report full-depth water column profiles for nitrogen and oxygen isotopic composition (δ15N and δ18O) of nitrate (NO3) during the GEOTRACES GA01 cruise (2014). This transect intersects the double gyre system of the subtropical and subpolar regions of the North Atlantic separated by a strong transition zone, the North Atlantic Current. The distribution of NO3 δ15N and δ18O shows that assimilation by phytoplankton is the main process controlling the NO3 isotopic composition in the upper 150m, with values increasing in a NO3 δ18O versus δ15N space along a line with a slope of one toward the surface. In the subpolar gyre, a single relationship between the degree of NO3 consumption and residual NO3 δ15N supports the view that NO3 is supplied via Ekman upwelling and deep winter convection, and progressively consumed during the Ekman transport of surface water southward. The co-occurrence of partial NO3 assimilation and nitrification in the deep mixed layer of the subpolar gyre elevates subsurface NO3 δ18O in comparison to deep oceanic values. This signal propagates through isopycnal exchanges to greater depths at lower latitudes. With recirculation in the subtropical gyre, cycles of quantitative consumption-nitrification progressively decrease subsurface NO3 δ18O toward the δ18O of regenerated NO3. The low NO3 δ15N observed south of the Subarctic Front is mostly explained by N2 fixation, although a contribution from the Mediterranean outflow is required to explain the lower NO3 δ15N signal observed between 600 and 1500 m depth close to the Iberian margin.",

author = "Florian Deman and Debany Fonseca-Batista and Arnout Roukaerts and M. Garcia-Ibanez and {Le Roy}, Emilie and E.P.D.N. Thilakarathne and Marc Elskens and Frank Dehairs and Fran{\c c}ois Fripiat",

note = "Funding Information: The authors thank the captain and crew of the R/V for organizing the logistics on board as well as chief scientists G. Sarthou and P. Lherminier for their assistance and support during the GEOVIDE expedition. P. Lherminier, P. Tr{\'e}guer, F. P{\'e}rez and C. Schmechtig are acknowledged for providing CTD and nutrients concentration data. The GEOVIDE project was co‐funded by the French national program LEFE/INSU (GEOVIDE), ANR Blanc (GEOVIDE) and RPDOC, LabEX MER and IFREMER. F. Deman was supported by the Belgian Federal Science Policy Office (Belspo contract BL/12/C63) while writing the manuscript. This work was financed by Flanders Research Foundation (FWO contract G0715.12N) and Vrije Universiteit Brussel, R&D, Strategic Research Plan “Tracers of Past & Present Global Changes”. During the preparation of the manuscript, Debany Fonseca‐Batista was supported by funding from the Canada First Research Excellence Fund, through an International Postdoctoral Fellowship of the Ocean Frontier Institute (OFI) at Dalhousie University. Pourquoi Pas? Funding Information: The authors thank the captain and crew of the R/V Pourquoi Pas? for organizing the logistics on board as well as chief scientists G. Sarthou and P. Lherminier for their assistance and support during the GEOVIDE expedition. P. Lherminier, P. Tr{\'e}guer, F. P{\'e}rez and C. Schmechtig are acknowledged for providing CTD and nutrients concentration data. The GEOVIDE project was co-funded by the French national program LEFE/INSU (GEOVIDE), ANR Blanc (GEOVIDE) and RPDOC, LabEX MER and IFREMER. F. Deman was supported by the Belgian Federal Science Policy Office (Belspo contract BL/12/C63) while writing the manuscript. This work was financed by Flanders Research Foundation (FWO contract G0715.12N) and Vrije Universiteit Brussel, R&D, Strategic Research Plan “Tracers of Past & Present Global Changes”. During the preparation of the manuscript, Debany Fonseca-Batista was supported by funding from the Canada First Research Excellence Fund, through an International Postdoctoral Fellowship of the Ocean Frontier Institute (OFI) at Dalhousie University. Publisher Copyright: {\textcopyright} 2021. American Geophysical Union. All Rights Reserved. Copyright: Copyright 2021 Elsevier B.V., All rights reserved.",

year = "2021",

month = apr,

doi = "10.1029/2020GB006887",

language = "English",

volume = "35",

journal = "Global Biogeochemical Cycles",

issn = "1944-9224",

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T1 - Nitrate Supply Routes and Impact of Internal Cycling in the North Atlantic Ocean Inferred From Nitrate Isotopic Composition

AU - Deman, Florian

AU - Fonseca-Batista, Debany

AU - Roukaerts, Arnout

AU - Garcia-Ibanez, M.

AU - Le Roy, Emilie

AU - Thilakarathne, E.P.D.N.

AU - Elskens, Marc

AU - Dehairs, Frank

AU - Fripiat, François

N1 - Funding Information: The authors thank the captain and crew of the R/V for organizing the logistics on board as well as chief scientists G. Sarthou and P. Lherminier for their assistance and support during the GEOVIDE expedition. P. Lherminier, P. Tréguer, F. Pérez and C. Schmechtig are acknowledged for providing CTD and nutrients concentration data. The GEOVIDE project was co‐funded by the French national program LEFE/INSU (GEOVIDE), ANR Blanc (GEOVIDE) and RPDOC, LabEX MER and IFREMER. F. Deman was supported by the Belgian Federal Science Policy Office (Belspo contract BL/12/C63) while writing the manuscript. This work was financed by Flanders Research Foundation (FWO contract G0715.12N) and Vrije Universiteit Brussel, R&D, Strategic Research Plan “Tracers of Past & Present Global Changes”. During the preparation of the manuscript, Debany Fonseca‐Batista was supported by funding from the Canada First Research Excellence Fund, through an International Postdoctoral Fellowship of the Ocean Frontier Institute (OFI) at Dalhousie University. Pourquoi Pas? Funding Information: The authors thank the captain and crew of the R/V Pourquoi Pas? for organizing the logistics on board as well as chief scientists G. Sarthou and P. Lherminier for their assistance and support during the GEOVIDE expedition. P. Lherminier, P. Tréguer, F. Pérez and C. Schmechtig are acknowledged for providing CTD and nutrients concentration data. The GEOVIDE project was co-funded by the French national program LEFE/INSU (GEOVIDE), ANR Blanc (GEOVIDE) and RPDOC, LabEX MER and IFREMER. F. Deman was supported by the Belgian Federal Science Policy Office (Belspo contract BL/12/C63) while writing the manuscript. This work was financed by Flanders Research Foundation (FWO contract G0715.12N) and Vrije Universiteit Brussel, R&D, Strategic Research Plan “Tracers of Past & Present Global Changes”. During the preparation of the manuscript, Debany Fonseca-Batista was supported by funding from the Canada First Research Excellence Fund, through an International Postdoctoral Fellowship of the Ocean Frontier Institute (OFI) at Dalhousie University. Publisher Copyright: © 2021. American Geophysical Union. All Rights Reserved. Copyright: Copyright 2021 Elsevier B.V., All rights reserved.

PY - 2021/4

Y1 - 2021/4

N2 - In this study we report full-depth water column profiles for nitrogen and oxygen isotopic composition (δ15N and δ18O) of nitrate (NO3) during the GEOTRACES GA01 cruise (2014). This transect intersects the double gyre system of the subtropical and subpolar regions of the North Atlantic separated by a strong transition zone, the North Atlantic Current. The distribution of NO3 δ15N and δ18O shows that assimilation by phytoplankton is the main process controlling the NO3 isotopic composition in the upper 150m, with values increasing in a NO3 δ18O versus δ15N space along a line with a slope of one toward the surface. In the subpolar gyre, a single relationship between the degree of NO3 consumption and residual NO3 δ15N supports the view that NO3 is supplied via Ekman upwelling and deep winter convection, and progressively consumed during the Ekman transport of surface water southward. The co-occurrence of partial NO3 assimilation and nitrification in the deep mixed layer of the subpolar gyre elevates subsurface NO3 δ18O in comparison to deep oceanic values. This signal propagates through isopycnal exchanges to greater depths at lower latitudes. With recirculation in the subtropical gyre, cycles of quantitative consumption-nitrification progressively decrease subsurface NO3 δ18O toward the δ18O of regenerated NO3. The low NO3 δ15N observed south of the Subarctic Front is mostly explained by N2 fixation, although a contribution from the Mediterranean outflow is required to explain the lower NO3 δ15N signal observed between 600 and 1500 m depth close to the Iberian margin.

AB - In this study we report full-depth water column profiles for nitrogen and oxygen isotopic composition (δ15N and δ18O) of nitrate (NO3) during the GEOTRACES GA01 cruise (2014). This transect intersects the double gyre system of the subtropical and subpolar regions of the North Atlantic separated by a strong transition zone, the North Atlantic Current. The distribution of NO3 δ15N and δ18O shows that assimilation by phytoplankton is the main process controlling the NO3 isotopic composition in the upper 150m, with values increasing in a NO3 δ18O versus δ15N space along a line with a slope of one toward the surface. In the subpolar gyre, a single relationship between the degree of NO3 consumption and residual NO3 δ15N supports the view that NO3 is supplied via Ekman upwelling and deep winter convection, and progressively consumed during the Ekman transport of surface water southward. The co-occurrence of partial NO3 assimilation and nitrification in the deep mixed layer of the subpolar gyre elevates subsurface NO3 δ18O in comparison to deep oceanic values. This signal propagates through isopycnal exchanges to greater depths at lower latitudes. With recirculation in the subtropical gyre, cycles of quantitative consumption-nitrification progressively decrease subsurface NO3 δ18O toward the δ18O of regenerated NO3. The low NO3 δ15N observed south of the Subarctic Front is mostly explained by N2 fixation, although a contribution from the Mediterranean outflow is required to explain the lower NO3 δ15N signal observed between 600 and 1500 m depth close to the Iberian margin.

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U2 - 10.1029/2020GB006887

DO - 10.1029/2020GB006887

M3 - Article

SN - 1944-9224

VL - 35

JO - Global Biogeochemical Cycles

JF - Global Biogeochemical Cycles

IS - 4

M1 - e2020GB006887

ER -

Nitrate Supply Routes and Impact of Internal Cycling in the North Atlantic Ocean Inferred From Nitrate Isotopic Composition

Abstract

Bibliographical note

Access to Document

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Other files and links

Fingerprint

HERC46: FWO Hercules MZW: A walk on the wild side of stable isotope biogeochemistry

OZR3252: Cofinancing OZR FWO Hercules MZW equipment: A walk on the wild side of stable isotope biogeochemistry...

HERC9: Upgrade of the Stable Isotope Laboratory

N2 fixation as a source of new nitrogen in the Atlantic Ocean

AMGC - Isotope Ratio Mass Spectrometry Laboratory (IRMS)

Cite this

Nitrate Supply Routes and Impact of Internal Cycling in the North Atlantic Ocean Inferred From Nitrate Isotopic Composition

Abstract

Bibliographical note

Access to Document

Handle.net

Other files and links

Fingerprint

Projects

HERC46: FWO Hercules MZW: A walk on the wild side of stable isotope biogeochemistry

OZR3252: Cofinancing OZR FWO Hercules MZW equipment: A walk on the wild side of stable isotope biogeochemistry...

HERC9: Upgrade of the Stable Isotope Laboratory

Research output

N2 fixation as a source of new nitrogen in the Atlantic Ocean

Equipment

AMGC - Isotope Ratio Mass Spectrometry Laboratory (IRMS)

Cite this