Future Antarctic bed topography and its implications for ice sheet dynamics

The Antarctic bedrock is evolving as the solid Earth responds to the past and ongoing evolution of the ice sheet. A recently improved ice loading history suggests that the Antarctic Ice Sheet (AIS) has generally been losing its mass since the Last Glacial Maximum. In a sustained warming climate, the...

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Main Authors: Adhikari, S, Ivins, ER, Larour, E, Seroussi, H, Morlighem, M, Nowicki, S
Format: Article in Journal/Newspaper
Language:unknown
Published: eScholarship, University of California 2014
Subjects:
Online Access:https://escholarship.org/uc/item/07n0v6ck
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spelling ftcdlib:oai:escholarship.org/ark:/13030/qt07n0v6ck 2023-05-15T13:22:10+02:00 Future Antarctic bed topography and its implications for ice sheet dynamics Adhikari, S Ivins, ER Larour, E Seroussi, H Morlighem, M Nowicki, S 569 - 584 2014-06-30 application/pdf https://escholarship.org/uc/item/07n0v6ck unknown eScholarship, University of California qt07n0v6ck https://escholarship.org/uc/item/07n0v6ck CC-BY CC-BY Solid Earth, vol 5, iss 1 Geology article 2014 ftcdlib 2020-03-20T23:55:48Z The Antarctic bedrock is evolving as the solid Earth responds to the past and ongoing evolution of the ice sheet. A recently improved ice loading history suggests that the Antarctic Ice Sheet (AIS) has generally been losing its mass since the Last Glacial Maximum. In a sustained warming climate, the AIS is predicted to retreat at a greater pace, primarily via melting beneath the ice shelves. We employ the glacial isostatic adjustment (GIA) capability of the Ice Sheet System Model (ISSM) to combine these past and future ice loadings and provide the new solid Earth computations for the AIS. We find that past loading is relatively less important than future loading for the evolution of the future bed topography. Our computations predict that the West Antarctic Ice Sheet (WAIS) may uplift by a few meters and a few tens of meters at years AD 2100 and 2500, respectively, and that the East Antarctic Ice Sheet is likely to remain unchanged or subside minimally except around the Amery Ice Shelf. The Amundsen Sea Sector in particular is predicted to rise at the greatest rate; one hundred years of ice evolution in this region, for example, predicts that the coastline of Pine Island Bay will approach roughly 45 mm yr−1 in viscoelastic vertical motion. Of particular importance, we systematically demonstrate that the effect of a pervasive and large GIA uplift in the WAIS is generally associated with the flattening of reverse bed slope, reduction of local sea depth, and thus the extension of grounding line (GL) towards the continental shelf. Using the 3-D higher-order ice flow capability of ISSM, such a migration of GL is shown to inhibit the ice flow. This negative feedback between the ice sheet and the solid Earth may promote stability in marine portions of the ice sheet in the future. © Author(s) 2014. CC Attribution 3.0 License. Article in Journal/Newspaper Amery Ice Shelf Amundsen Sea Antarc* Antarctic Ice Sheet Ice Shelf Ice Shelves Pine Island Bay University of California: eScholarship Amery ENVELOPE(-94.063,-94.063,56.565,56.565) Amery Ice Shelf ENVELOPE(71.000,71.000,-69.750,-69.750) Amundsen Sea Antarctic East Antarctic Ice Sheet Island Bay ENVELOPE(-109.085,-109.085,59.534,59.534) Pine Island Bay ENVELOPE(-102.000,-102.000,-74.750,-74.750) The Antarctic West Antarctic Ice Sheet
institution Open Polar
collection University of California: eScholarship
op_collection_id ftcdlib
language unknown
topic Geology
spellingShingle Geology
Adhikari, S
Ivins, ER
Larour, E
Seroussi, H
Morlighem, M
Nowicki, S
Future Antarctic bed topography and its implications for ice sheet dynamics
topic_facet Geology
description The Antarctic bedrock is evolving as the solid Earth responds to the past and ongoing evolution of the ice sheet. A recently improved ice loading history suggests that the Antarctic Ice Sheet (AIS) has generally been losing its mass since the Last Glacial Maximum. In a sustained warming climate, the AIS is predicted to retreat at a greater pace, primarily via melting beneath the ice shelves. We employ the glacial isostatic adjustment (GIA) capability of the Ice Sheet System Model (ISSM) to combine these past and future ice loadings and provide the new solid Earth computations for the AIS. We find that past loading is relatively less important than future loading for the evolution of the future bed topography. Our computations predict that the West Antarctic Ice Sheet (WAIS) may uplift by a few meters and a few tens of meters at years AD 2100 and 2500, respectively, and that the East Antarctic Ice Sheet is likely to remain unchanged or subside minimally except around the Amery Ice Shelf. The Amundsen Sea Sector in particular is predicted to rise at the greatest rate; one hundred years of ice evolution in this region, for example, predicts that the coastline of Pine Island Bay will approach roughly 45 mm yr−1 in viscoelastic vertical motion. Of particular importance, we systematically demonstrate that the effect of a pervasive and large GIA uplift in the WAIS is generally associated with the flattening of reverse bed slope, reduction of local sea depth, and thus the extension of grounding line (GL) towards the continental shelf. Using the 3-D higher-order ice flow capability of ISSM, such a migration of GL is shown to inhibit the ice flow. This negative feedback between the ice sheet and the solid Earth may promote stability in marine portions of the ice sheet in the future. © Author(s) 2014. CC Attribution 3.0 License.
format Article in Journal/Newspaper
author Adhikari, S
Ivins, ER
Larour, E
Seroussi, H
Morlighem, M
Nowicki, S
author_facet Adhikari, S
Ivins, ER
Larour, E
Seroussi, H
Morlighem, M
Nowicki, S
author_sort Adhikari, S
title Future Antarctic bed topography and its implications for ice sheet dynamics
title_short Future Antarctic bed topography and its implications for ice sheet dynamics
title_full Future Antarctic bed topography and its implications for ice sheet dynamics
title_fullStr Future Antarctic bed topography and its implications for ice sheet dynamics
title_full_unstemmed Future Antarctic bed topography and its implications for ice sheet dynamics
title_sort future antarctic bed topography and its implications for ice sheet dynamics
publisher eScholarship, University of California
publishDate 2014
url https://escholarship.org/uc/item/07n0v6ck
op_coverage 569 - 584
long_lat ENVELOPE(-94.063,-94.063,56.565,56.565)
ENVELOPE(71.000,71.000,-69.750,-69.750)
ENVELOPE(-109.085,-109.085,59.534,59.534)
ENVELOPE(-102.000,-102.000,-74.750,-74.750)
geographic Amery
Amery Ice Shelf
Amundsen Sea
Antarctic
East Antarctic Ice Sheet
Island Bay
Pine Island Bay
The Antarctic
West Antarctic Ice Sheet
geographic_facet Amery
Amery Ice Shelf
Amundsen Sea
Antarctic
East Antarctic Ice Sheet
Island Bay
Pine Island Bay
The Antarctic
West Antarctic Ice Sheet
genre Amery Ice Shelf
Amundsen Sea
Antarc*
Antarctic
Ice Sheet
Ice Shelf
Ice Shelves
Pine Island Bay
genre_facet Amery Ice Shelf
Amundsen Sea
Antarc*
Antarctic
Ice Sheet
Ice Shelf
Ice Shelves
Pine Island Bay
op_source Solid Earth, vol 5, iss 1
op_relation qt07n0v6ck
https://escholarship.org/uc/item/07n0v6ck
op_rights CC-BY
op_rightsnorm CC-BY
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