Water masses as a unifying framework for understanding the Southern Ocean Carbon Cycle

The scientific motivation for this study is to understand the processes in the ocean interior controlling carbon transfer across 30S. To address this, we have developed a unified framework for understanding the interplay between physical drivers such as buoyancy fluxes and ocean mixing, and carbon-s...

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Published in:Biogeosciences
Main Authors: Iudicone, D., Rodgers, K.B., Stendardo, I., Aumont, O., Madec, G., Bopp, L., Mangoni, O., Ribera d'Alcala', M.
Format: Article in Journal/Newspaper
Language:unknown
Published: 2011
Subjects:
Antarctic
Southern Ocean
Antarc*
Online Access:https://eprints.soton.ac.uk/189497/
id ftsouthampton:oai:eprints.soton.ac.uk:189497
record_format openpolar
spelling ftsouthampton:oai:eprints.soton.ac.uk:189497 2023-07-30T03:59:20+02:00 Water masses as a unifying framework for understanding the Southern Ocean Carbon Cycle Iudicone, D. Rodgers, K.B. Stendardo, I. Aumont, O. Madec, G. Bopp, L. Mangoni, O. Ribera d'Alcala', M. 2011 https://eprints.soton.ac.uk/189497/ unknown Iudicone, D., Rodgers, K.B., Stendardo, I., Aumont, O., Madec, G., Bopp, L., Mangoni, O. and Ribera d'Alcala', M. (2011) Water masses as a unifying framework for understanding the Southern Ocean Carbon Cycle. Biogeosciences, 8 (5), 1031-1052. (doi:10.5194/bg-8-1031-2011 <http://dx.doi.org/10.5194/bg-8-1031-2011>). Article PeerReviewed 2011 ftsouthampton https://doi.org/10.5194/bg-8-1031-2011 2023-07-09T21:22:22Z The scientific motivation for this study is to understand the processes in the ocean interior controlling carbon transfer across 30S. To address this, we have developed a unified framework for understanding the interplay between physical drivers such as buoyancy fluxes and ocean mixing, and carbon-specific processes such as biology, gas exchange and carbon mixing. Given the importance of density in determining the ocean interior structure and circulation, the framework is one that is organized by density and water masses, and it makes combined use of Eulerian and Lagrangian diagnostics. This is achieved through application to a global ice-ocean circulation model and an ocean biogeochemistry model, with both components being part of the widely-used IPSL coupled ocean/atmosphere/carbon cycle model. Our main new result is the dominance of the overturning circulation (identified by water masses) in setting the vertical distribution of carbon transport from the Southern Ocean towards the global ocean. A net contrast emerges between the role of Subantarctic Mode Water (SAMW), associated with large northward transport and ingassing, and Antarctic IntermediateWater (AAIW), associated with a much smaller export and outgassing. The differences in their export rate reflects differences in their water mass formation processes. For SAMW, two-thirds of the surface waters are provided as a result of the densification of thermocline water (TW), and upon densification this water carries with it a substantial diapycnal flux of dissolved inorganic carbon (DIC). For AAIW, principal formatin processes include buoyancy forcing and mixing, with these serving to lighten CDW. An additional important formation pathway of AAIW is through the effect of interior processing (mixing, including cabelling) that serve to densify SAMW. A quantitative evaluation of the contribution of mixing, biology and gas exchange to the DIC evolution per water mass reveals that mixing and, secondarily, gas exchange, effectively nearly balance biology on annual ... Article in Journal/Newspaper Antarc* Antarctic Southern Ocean University of Southampton: e-Prints Soton Antarctic Southern Ocean Biogeosciences 8 5 1031 1052
institution Open Polar
collection University of Southampton: e-Prints Soton
op_collection_id ftsouthampton
language unknown
description The scientific motivation for this study is to understand the processes in the ocean interior controlling carbon transfer across 30S. To address this, we have developed a unified framework for understanding the interplay between physical drivers such as buoyancy fluxes and ocean mixing, and carbon-specific processes such as biology, gas exchange and carbon mixing. Given the importance of density in determining the ocean interior structure and circulation, the framework is one that is organized by density and water masses, and it makes combined use of Eulerian and Lagrangian diagnostics. This is achieved through application to a global ice-ocean circulation model and an ocean biogeochemistry model, with both components being part of the widely-used IPSL coupled ocean/atmosphere/carbon cycle model. Our main new result is the dominance of the overturning circulation (identified by water masses) in setting the vertical distribution of carbon transport from the Southern Ocean towards the global ocean. A net contrast emerges between the role of Subantarctic Mode Water (SAMW), associated with large northward transport and ingassing, and Antarctic IntermediateWater (AAIW), associated with a much smaller export and outgassing. The differences in their export rate reflects differences in their water mass formation processes. For SAMW, two-thirds of the surface waters are provided as a result of the densification of thermocline water (TW), and upon densification this water carries with it a substantial diapycnal flux of dissolved inorganic carbon (DIC). For AAIW, principal formatin processes include buoyancy forcing and mixing, with these serving to lighten CDW. An additional important formation pathway of AAIW is through the effect of interior processing (mixing, including cabelling) that serve to densify SAMW. A quantitative evaluation of the contribution of mixing, biology and gas exchange to the DIC evolution per water mass reveals that mixing and, secondarily, gas exchange, effectively nearly balance biology on annual ...
format Article in Journal/Newspaper
author Iudicone, D.
Rodgers, K.B.
Stendardo, I.
Aumont, O.
Madec, G.
Bopp, L.
Mangoni, O.
Ribera d'Alcala', M.
spellingShingle Iudicone, D.
Rodgers, K.B.
Stendardo, I.
Aumont, O.
Madec, G.
Bopp, L.
Mangoni, O.
Ribera d'Alcala', M.
Water masses as a unifying framework for understanding the Southern Ocean Carbon Cycle
author_facet Iudicone, D.
Rodgers, K.B.
Stendardo, I.
Aumont, O.
Madec, G.
Bopp, L.
Mangoni, O.
Ribera d'Alcala', M.
author_sort Iudicone, D.
title Water masses as a unifying framework for understanding the Southern Ocean Carbon Cycle
title_short Water masses as a unifying framework for understanding the Southern Ocean Carbon Cycle
title_full Water masses as a unifying framework for understanding the Southern Ocean Carbon Cycle
title_fullStr Water masses as a unifying framework for understanding the Southern Ocean Carbon Cycle
title_full_unstemmed Water masses as a unifying framework for understanding the Southern Ocean Carbon Cycle
title_sort water masses as a unifying framework for understanding the southern ocean carbon cycle
publishDate 2011
url https://eprints.soton.ac.uk/189497/
geographic Antarctic
Southern Ocean
geographic_facet Antarctic
Southern Ocean
genre Antarc*
Antarctic
Southern Ocean
genre_facet Antarc*
Antarctic
Southern Ocean
op_relation Iudicone, D., Rodgers, K.B., Stendardo, I., Aumont, O., Madec, G., Bopp, L., Mangoni, O. and Ribera d'Alcala', M. (2011) Water masses as a unifying framework for understanding the Southern Ocean Carbon Cycle. Biogeosciences, 8 (5), 1031-1052. (doi:10.5194/bg-8-1031-2011 <http://dx.doi.org/10.5194/bg-8-1031-2011>).
op_doi https://doi.org/10.5194/bg-8-1031-2011
container_title Biogeosciences
container_volume 8
container_issue 5
container_start_page 1031
op_container_end_page 1052
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