Observations beneath Pine Island Glacier in West Antarctica and implications for its retreat
Observations beneath Pine Island Glacier in West Antarctica and implications for its retreat
Thinning ice in West Antarctica, resulting from acceleration in the flow of outlet glaciers, is at present contributing about 10% of the observed rise in global sea level. Pine Island Glacier in particular has shown nearly continuous acceleration and thinning, throughout the short observational record. The floating ice shelf that forms where the glacier reaches the coast has been thinning rapidly, driven by changes in ocean heat transport beneath it. As a result, the line that separates grounded and floating ice has retreated inland. These events have been postulated as the cause for the inland thinning and acceleration. Here we report evidence gathered by an autonomous underwater vehicle operating beneath the ice shelf that Pine Island Glacier was recently grounded on a transverse ridge in the sea floor. Warm sea water now flows through a widening gap above the submarine ridge, rapidly melting the thick ice of the newly formed upstream half of the ice shelf. The present evolution of Pine Island Glacier is thus part of a longer-term trend that has moved the downstream limit of grounded ice inland by 30?km, into water that is 300?m deeper than over the ridge crest. The pace and ultimate extent of such potentially unstable retreat are central to the debate over the possibility of widespread ice-sheet collapse triggered by climate change.
468 -472
Jenkins, Adrian
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Dutrieux, Pierre
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Jacobs, Stanley S.
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McPhail, Stephen D.
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Perrett, James R.
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Webb, Andrew T.
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White, David
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July 2010
Jenkins, Adrian
ae892509-d8d8-4176-99b2-66cc717ef376
Dutrieux, Pierre
366b1813-3d70-4202-aabb-0e314e3d99b7
Jacobs, Stanley S.
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McPhail, Stephen D.
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Perrett, James R.
6392a5df-7574-4780-bb36-e5d4d3fd1d11
Webb, Andrew T.
4e153c92-56e5-4ef0-9d10-e22693abf51a
White, David
81c6bf5a-52a2-4f06-b694-0d2a57b7c13a
Jenkins, Adrian, Dutrieux, Pierre, Jacobs, Stanley S., McPhail, Stephen D., Perrett, James R., Webb, Andrew T. and White, David
(2010)
Observations beneath Pine Island Glacier in West Antarctica and implications for its retreat.
Nature Geoscience, 3 (7), .
(doi:10.1038/ngeo890).
Abstract
Thinning ice in West Antarctica, resulting from acceleration in the flow of outlet glaciers, is at present contributing about 10% of the observed rise in global sea level. Pine Island Glacier in particular has shown nearly continuous acceleration and thinning, throughout the short observational record. The floating ice shelf that forms where the glacier reaches the coast has been thinning rapidly, driven by changes in ocean heat transport beneath it. As a result, the line that separates grounded and floating ice has retreated inland. These events have been postulated as the cause for the inland thinning and acceleration. Here we report evidence gathered by an autonomous underwater vehicle operating beneath the ice shelf that Pine Island Glacier was recently grounded on a transverse ridge in the sea floor. Warm sea water now flows through a widening gap above the submarine ridge, rapidly melting the thick ice of the newly formed upstream half of the ice shelf. The present evolution of Pine Island Glacier is thus part of a longer-term trend that has moved the downstream limit of grounded ice inland by 30?km, into water that is 300?m deeper than over the ridge crest. The pace and ultimate extent of such potentially unstable retreat are central to the debate over the possibility of widespread ice-sheet collapse triggered by climate change.
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Jenkins_preprint.pdf
- Author's Original
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Published date: July 2010
Organisations:
Ocean Technology and Engineering
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Local EPrints ID: 159453
URI: http://eprints.soton.ac.uk/id/eprint/159453
ISSN: 1752-0894
PURE UUID: 1877ab80-27c6-4dd8-8de0-5269007742f5
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Date deposited: 30 Jun 2010 13:16
Last modified: 14 Mar 2024 01:54
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Author:
Adrian Jenkins
Author:
Pierre Dutrieux
Author:
Stanley S. Jacobs
Author:
Stephen D. McPhail
Author:
James R. Perrett
Author:
Andrew T. Webb
Author:
David White
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