Winter sea ice edge shaped by Antarctic Circumpolar Current pathways
Winter sea ice edge shaped by Antarctic Circumpolar Current pathways
The Antarctic Circumpolar Current (ACC) is often considered a natural barrier for the northward expansion of the Antarctic sea ice, but the underlying processes remain little explored. Here, we focus on the main fronts of the ACC – as a measure of the current system's path – to study how they influence the mean state of sea ice. We find that the latitude of all ACC fronts as a function of longitude shows a correlation above 0.85 with the climatological mean latitude of the winter sea ice edge, indicating a strong link across all sectors of the Southern Ocean. Among the ACC fronts, the Polar Front is identified as the best indicator for studying the ACC's influence on sea ice, as it marks a distinct transition in upper-ocean water mass properties and is consistently found north of the sea ice edge. The distance between the Polar Front and the sea ice edge decreases when the Polar Front lies farther south, due to the presence of warmer waters at higher latitudes. These warmer waters enable efficient heat transport toward the ice edge and constitute a barrier to sea ice expansion, via two main mechanisms. First, the ocean carries heat from the Polar Front toward the pole, in particular through the contribution of mesoscale ocean eddies formed downstream of major underwater topographic features. Second, warmer oceanic surface waters near the front heat the atmosphere above, which then carries this heat poleward towards the ice, especially in regions with more southward-directed winds. Since the Polar Front's path is largely shaped by topographic barriers, these results indicate why the position of the winter sea ice edge is strongly constrained, under current conditions, by bathymetry.
5763-5779
Goosse, Hugues
33c33c55-356b-48ec-be78-3e9eb5d04f29
Libera, Stephy
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Garabato, Alberto C. Naveira
ef40856f-6d7a-493c-b364-3959e21c69a1
Richaud, Benjamin
c868470e-08ee-4785-8c9b-65fc796d4074
Silvano, Alessandro
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Vancoppenolle, Martin
c48d03ee-16ea-4e82-9119-c38d79093714
14 November 2025
Goosse, Hugues
33c33c55-356b-48ec-be78-3e9eb5d04f29
Libera, Stephy
a65e276b-aad9-47d4-b1b7-b7b2af2f0128
Garabato, Alberto C. Naveira
ef40856f-6d7a-493c-b364-3959e21c69a1
Richaud, Benjamin
c868470e-08ee-4785-8c9b-65fc796d4074
Silvano, Alessandro
54a4322b-c52d-4179-a414-dc108c416ec9
Vancoppenolle, Martin
c48d03ee-16ea-4e82-9119-c38d79093714
Goosse, Hugues, Libera, Stephy, Garabato, Alberto C. Naveira, Richaud, Benjamin, Silvano, Alessandro and Vancoppenolle, Martin
(2025)
Winter sea ice edge shaped by Antarctic Circumpolar Current pathways.
The Cryosphere, 19 (11), .
(doi:10.5194/tc-19-5763-2025).
Abstract
The Antarctic Circumpolar Current (ACC) is often considered a natural barrier for the northward expansion of the Antarctic sea ice, but the underlying processes remain little explored. Here, we focus on the main fronts of the ACC – as a measure of the current system's path – to study how they influence the mean state of sea ice. We find that the latitude of all ACC fronts as a function of longitude shows a correlation above 0.85 with the climatological mean latitude of the winter sea ice edge, indicating a strong link across all sectors of the Southern Ocean. Among the ACC fronts, the Polar Front is identified as the best indicator for studying the ACC's influence on sea ice, as it marks a distinct transition in upper-ocean water mass properties and is consistently found north of the sea ice edge. The distance between the Polar Front and the sea ice edge decreases when the Polar Front lies farther south, due to the presence of warmer waters at higher latitudes. These warmer waters enable efficient heat transport toward the ice edge and constitute a barrier to sea ice expansion, via two main mechanisms. First, the ocean carries heat from the Polar Front toward the pole, in particular through the contribution of mesoscale ocean eddies formed downstream of major underwater topographic features. Second, warmer oceanic surface waters near the front heat the atmosphere above, which then carries this heat poleward towards the ice, especially in regions with more southward-directed winds. Since the Polar Front's path is largely shaped by topographic barriers, these results indicate why the position of the winter sea ice edge is strongly constrained, under current conditions, by bathymetry.
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tc-19-5763-2025
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Accepted/In Press date: 15 October 2025
e-pub ahead of print date: 14 November 2025
Published date: 14 November 2025
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Local EPrints ID: 511782
URI: http://eprints.soton.ac.uk/id/eprint/511782
ISSN: 1994-0416
PURE UUID: 55fbf4f2-0ff4-47f6-9f91-6a9db5f2b61a
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Date deposited: 02 Jun 2026 16:42
Last modified: 03 Jun 2026 01:59
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Author:
Hugues Goosse
Author:
Stephy Libera
Author:
Alberto C. Naveira Garabato
Author:
Benjamin Richaud
Author:
Martin Vancoppenolle
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