Deep temperature variability in Drake Passage
Deep temperature variability in Drake Passage
Observations made on 21 occupations between 1993 and 2016 of GO-SHIP line SR1b in eastern Drake Passage show an average temperature of 0.53°C deeper than 2000 dbar, with no significant trend, but substantial year-to-year variability (standard deviation 0.08°C). Using a neutral density framework to decompose the temperature variability into isopycnal displacement (heave) and isopycnal property change components shows that approximately 95% of the year-to-year variance in deep temperature is due to heave. Changes on isopycnals make a small contribution to year-to-year variability but contribute a significant trend of -1.4±0.6 m°C per year, largest for density (?n)?>?28.1, south of the Polar Front (PF). The heave component is depth-coherent and results from either vertical or horizontal motions of neutral density surfaces, which trend upward and northward around the PF, downward for the densest levels in the southern section, and downward and southward in the Subantarctic Front and Southern Antarctic Circumpolar Current Front (SACCF). A proxy for the locations of the Antarctic Circumpolar Current (ACC) fronts is constructed from the repeat hydrographic data and has a strong relationship with deep ocean heat content, explaining 76% of deep temperature variance. The same frontal position proxy based on satellite altimeter-derived surface velocities explains 73% of deep temperature variance. The position of the PF plays the strongest role in this relationship between ACC fronts and deep temperature variability in Drake Passage, although much of the temperature variability in the southern half of the section can be explained by the position of the SACCF. This article is protected by copyright. All rights reserved.
Temperature, trends, Southern Ocean
713–725
Firing, Yvonne L.
2518c141-9864-4b97-a9ed-adbab90dca66
Mcdonagh, Elaine L.
47e26eeb-b774-4068-af07-31847e42b977
King, Brian A.
960f44b4-cc9c-4f77-b3c8-775530ac0061
Desbruyeres, Damien G.
3184ffa3-0366-4324-ab86-be7e456430ee
31 January 2017
Firing, Yvonne L.
2518c141-9864-4b97-a9ed-adbab90dca66
Mcdonagh, Elaine L.
47e26eeb-b774-4068-af07-31847e42b977
King, Brian A.
960f44b4-cc9c-4f77-b3c8-775530ac0061
Desbruyeres, Damien G.
3184ffa3-0366-4324-ab86-be7e456430ee
Firing, Yvonne L., Mcdonagh, Elaine L., King, Brian A. and Desbruyeres, Damien G.
(2017)
Deep temperature variability in Drake Passage.
Journal of Geophysical Research: Oceans, 122 (1), .
(doi:10.1002/2016JC012452).
Abstract
Observations made on 21 occupations between 1993 and 2016 of GO-SHIP line SR1b in eastern Drake Passage show an average temperature of 0.53°C deeper than 2000 dbar, with no significant trend, but substantial year-to-year variability (standard deviation 0.08°C). Using a neutral density framework to decompose the temperature variability into isopycnal displacement (heave) and isopycnal property change components shows that approximately 95% of the year-to-year variance in deep temperature is due to heave. Changes on isopycnals make a small contribution to year-to-year variability but contribute a significant trend of -1.4±0.6 m°C per year, largest for density (?n)?>?28.1, south of the Polar Front (PF). The heave component is depth-coherent and results from either vertical or horizontal motions of neutral density surfaces, which trend upward and northward around the PF, downward for the densest levels in the southern section, and downward and southward in the Subantarctic Front and Southern Antarctic Circumpolar Current Front (SACCF). A proxy for the locations of the Antarctic Circumpolar Current (ACC) fronts is constructed from the repeat hydrographic data and has a strong relationship with deep ocean heat content, explaining 76% of deep temperature variance. The same frontal position proxy based on satellite altimeter-derived surface velocities explains 73% of deep temperature variance. The position of the PF plays the strongest role in this relationship between ACC fronts and deep temperature variability in Drake Passage, although much of the temperature variability in the southern half of the section can be explained by the position of the SACCF. This article is protected by copyright. All rights reserved.
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Accepted/In Press date: 7 December 2016
e-pub ahead of print date: 31 January 2017
Published date: 31 January 2017
Keywords:
Temperature, trends, Southern Ocean
Organisations:
Marine Physics and Ocean Climate
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Local EPrints ID: 404485
URI: http://eprints.soton.ac.uk/id/eprint/404485
PURE UUID: 5ea8f643-e92d-4cc9-ab76-24aa72a8be67
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Date deposited: 09 Jan 2017 16:16
Last modified: 15 Mar 2024 04:08
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Author:
Yvonne L. Firing
Author:
Elaine L. Mcdonagh
Author:
Brian A. King
Author:
Damien G. Desbruyeres
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