Aerogeophysical evidence for active volcanism beneath the West Antarctic Ice Sheet

Although it is widely understood that the collapse of the West Antarctic Ice Sheet (WAIS) would cause a global sea-level rise of 6 m, there continues to be considerable debate about the response of this ice sheet to climate change. The stability of the WAIS, which is characterized by a bed grounded...

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Main Authors: Blankenship, Donald D., Bell, Robin E., Hodge, Steven M., Brozena, John M., Behrendt, John C.
Format: Other/Unknown Material
Language:unknown
Published: 1993
Subjects:
46
Antarctic
West Antarctic Ice Sheet
Antarc*
Ice Sheet
Online Access:http://ntrs.nasa.gov/search.jsp?R=19930022706
id ftnasantrs:oai:casi.ntrs.nasa.gov:19930022706
record_format openpolar
spelling ftnasantrs:oai:casi.ntrs.nasa.gov:19930022706 2023-05-15T14:04:19+02:00 Aerogeophysical evidence for active volcanism beneath the West Antarctic Ice Sheet Blankenship, Donald D. Bell, Robin E. Hodge, Steven M. Brozena, John M. Behrendt, John C. Unclassified, Unlimited, Publicly available Jul 1, 1993 http://ntrs.nasa.gov/search.jsp?R=19930022706 unknown http://ntrs.nasa.gov/search.jsp?R=19930022706 Accession ID: 93N31895 No Copyright Other Sources 46 NASA. Goddard Space Flight Center, The First Annual West Antarctic Ice Sheet (WAIS) Science Workshop; p 27 1993 ftnasantrs 2012-02-15T19:56:21Z Although it is widely understood that the collapse of the West Antarctic Ice Sheet (WAIS) would cause a global sea-level rise of 6 m, there continues to be considerable debate about the response of this ice sheet to climate change. The stability of the WAIS, which is characterized by a bed grounded well below sea level, may depend on geologically controlled conditions at the base, which are independent of climate. Ice streams moving up to 750 m/yr disperse material from the interior through to the oceans. As these ice streams tend to buffer the reservoir of slow-moving inland ice from exposure to oceanic degradation, understanding the ice-streaming process is important for evaluating WAIS stability. There is strong evidence that ice streams slide on a lubricating layer of water-saturated till. Development of this basal layer requires both water and easily eroded sediments. Active lithospheric extension may elevate regional heat flux, increase basal melting, and trigger ice streaming. If a geologically defined boundary with a sharp contrast in geothermal flux exists beneath the WAIS, ice streams may only be capable of operating as a buffer over a restricted region. Should ocean waters penetrate beyond this boundary, the ice-stream buffer would disappear, possibly triggering a collapse of the inland ice reservoir. Aerogeophysical evidence for active volcanism and elevated heat flux beneath the WAIS near the critical region where ice streaming begins is presented. Other/Unknown Material Antarc* Antarctic Ice Sheet NASA Technical Reports Server (NTRS) Antarctic West Antarctic Ice Sheet
institution Open Polar
collection NASA Technical Reports Server (NTRS)
op_collection_id ftnasantrs
language unknown
topic 46
spellingShingle 46
Blankenship, Donald D.
Bell, Robin E.
Hodge, Steven M.
Brozena, John M.
Behrendt, John C.
Aerogeophysical evidence for active volcanism beneath the West Antarctic Ice Sheet
topic_facet 46
description Although it is widely understood that the collapse of the West Antarctic Ice Sheet (WAIS) would cause a global sea-level rise of 6 m, there continues to be considerable debate about the response of this ice sheet to climate change. The stability of the WAIS, which is characterized by a bed grounded well below sea level, may depend on geologically controlled conditions at the base, which are independent of climate. Ice streams moving up to 750 m/yr disperse material from the interior through to the oceans. As these ice streams tend to buffer the reservoir of slow-moving inland ice from exposure to oceanic degradation, understanding the ice-streaming process is important for evaluating WAIS stability. There is strong evidence that ice streams slide on a lubricating layer of water-saturated till. Development of this basal layer requires both water and easily eroded sediments. Active lithospheric extension may elevate regional heat flux, increase basal melting, and trigger ice streaming. If a geologically defined boundary with a sharp contrast in geothermal flux exists beneath the WAIS, ice streams may only be capable of operating as a buffer over a restricted region. Should ocean waters penetrate beyond this boundary, the ice-stream buffer would disappear, possibly triggering a collapse of the inland ice reservoir. Aerogeophysical evidence for active volcanism and elevated heat flux beneath the WAIS near the critical region where ice streaming begins is presented.
format Other/Unknown Material
author Blankenship, Donald D.
Bell, Robin E.
Hodge, Steven M.
Brozena, John M.
Behrendt, John C.
author_facet Blankenship, Donald D.
Bell, Robin E.
Hodge, Steven M.
Brozena, John M.
Behrendt, John C.
author_sort Blankenship, Donald D.
title Aerogeophysical evidence for active volcanism beneath the West Antarctic Ice Sheet
title_short Aerogeophysical evidence for active volcanism beneath the West Antarctic Ice Sheet
title_full Aerogeophysical evidence for active volcanism beneath the West Antarctic Ice Sheet
title_fullStr Aerogeophysical evidence for active volcanism beneath the West Antarctic Ice Sheet
title_full_unstemmed Aerogeophysical evidence for active volcanism beneath the West Antarctic Ice Sheet
title_sort aerogeophysical evidence for active volcanism beneath the west antarctic ice sheet
publishDate 1993
url http://ntrs.nasa.gov/search.jsp?R=19930022706
op_coverage Unclassified, Unlimited, Publicly available
geographic Antarctic
West Antarctic Ice Sheet
geographic_facet Antarctic
West Antarctic Ice Sheet
genre Antarc*
Antarctic
Ice Sheet
genre_facet Antarc*
Antarctic
Ice Sheet
op_source Other Sources
op_relation http://ntrs.nasa.gov/search.jsp?R=19930022706
Accession ID: 93N31895
op_rights No Copyright
_version_ 1766275352180555776

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