Deglacial History of the West Antarctic Ice Sheet in the Western Amundsen Sea Embayment

The Amundsen Sea Embayment (ASE) drains approximately 35% of the West Antarctic Ice Sheet (WAIS) and is one of the most rapidly changing parts of the cryosphere. In order to predict future ice sheet behaviour, modellers require long-term records of ice-sheet melting to constrain and build confidence...

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Published in:Quaternary Science Reviews
Main Authors: Smith, James A., Hillenbrand, Claus-Dieter, Kuhn, Gerhard, Larter, Robert D., Graham, Alastair G. C., Ehrmann, Werner, Moreton, Steven G., Forwick, Matthias
Format: Article in Journal/Newspaper
Language:unknown
Published: Digital Commons @ University of South Florida 2011
Subjects:
West Antarctic Ice Sheet (WAIS)
Last Glacial Maximum (LGM)
Amundsen sea
Dating
Deglaciation
Reverse slope
Life Sciences
Antarctic
Amundsen Sea
West Antarctic Ice Sheet
Antarc*
Ice Sheet
Ice Shelf
Iceberg*
Online Access:https://digitalcommons.usf.edu/msc_facpub/1528
https://doi.org/10.1016/j.quascirev.2010.11.020
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spelling ftunisfloridatam:oai:digitalcommons.usf.edu:msc_facpub-2585 2023-05-15T13:23:57+02:00 Deglacial History of the West Antarctic Ice Sheet in the Western Amundsen Sea Embayment Smith, James A. Hillenbrand, Claus-Dieter Kuhn, Gerhard Larter, Robert D. Graham, Alastair G. C. Ehrmann, Werner Moreton, Steven G. Forwick, Matthias 2011-01-01T08:00:00Z https://digitalcommons.usf.edu/msc_facpub/1528 https://doi.org/10.1016/j.quascirev.2010.11.020 unknown Digital Commons @ University of South Florida https://digitalcommons.usf.edu/msc_facpub/1528 https://doi.org/10.1016/j.quascirev.2010.11.020 Marine Science Faculty Publications West Antarctic Ice Sheet (WAIS) Last Glacial Maximum (LGM) Amundsen sea Dating Deglaciation Reverse slope Life Sciences article 2011 ftunisfloridatam https://doi.org/10.1016/j.quascirev.2010.11.020 2022-01-20T18:40:02Z The Amundsen Sea Embayment (ASE) drains approximately 35% of the West Antarctic Ice Sheet (WAIS) and is one of the most rapidly changing parts of the cryosphere. In order to predict future ice sheet behaviour, modellers require long-term records of ice-sheet melting to constrain and build confidence in their simulations. Here, we present detailed marine geological and radiocarbon data along three palaeo-ice stream tributary troughs in the western ASE to establish vital information on the timing of deglaciation of the WAIS since the Last Glacial Maximum (LGM). We have undertaken multi-proxy analyses of the cores (core description, shear strength, x-radiographs, magnetic susceptibility, wet bulk density, total organic carbon/nitrogen, carbonate content and clay mineral analyses) in order to: (1) characterise the sedimentological facies and depositional environments; and (2) identify the horizon(s) in each core that would yield the most reliable age for deglaciation. In accordance with previous studies we identify three key facies, which offer the most reliable stratigraphies for dating deglaciation by recording the transition from a grounded ice sheet to open marine environments. These facies are: i) subglacial, ii) proximal grounding line, and iii) seasonal open marine. In addition, we incorporate ages from other facies (e.g., glaciomarine diamictons deposited at some distance from the grounding line, such as glaciogenic debris flows and iceberg-rafted diamictons and turbates) into our deglacial model. In total, we have dated 78 samples (mainly the acid insoluble organic (AIO) fraction, but also calcareous foraminifers), which include 63 downcore and 15 surface samples. Through careful sample selection prior to dating, we have established a robust deglacial chronology for this sector of the WAIS. Our data show that deglaciation of the western ASE was probably underway as early as 22,351 calibrated years before present (cal yr BP), reaching the mid-shelf by 13,837 cal yr BP and the inner shelf to within c.10–12 km of the present ice shelf front between 12,618 and 10,072 cal yr BP. The deglacial steps in the western ASE broadly coincide with the rapid rises in sea-level associated with global meltwater pulses 1a and 1b, although given the potential dating uncertainty, additional, more precise ages are required before these findings can be fully substantiated. Finally, we show that the rate of ice-sheet retreat increased across the deep (up to1600 m) basins of the inner shelf, highlighting the importance of reverse slope and pinning points in accelerated phases of deglaciation. Article in Journal/Newspaper Amundsen Sea Antarc* Antarctic Ice Sheet Ice Shelf Iceberg* Digital Commons University of South Florida (USF) Antarctic Amundsen Sea West Antarctic Ice Sheet Quaternary Science Reviews 30 5-6 488 505
institution Open Polar
collection Digital Commons University of South Florida (USF)
op_collection_id ftunisfloridatam
language unknown
topic West Antarctic Ice Sheet (WAIS)
Last Glacial Maximum (LGM)
Amundsen sea
Dating
Deglaciation
Reverse slope
Life Sciences
spellingShingle West Antarctic Ice Sheet (WAIS)
Last Glacial Maximum (LGM)
Amundsen sea
Dating
Deglaciation
Reverse slope
Life Sciences
Smith, James A.
Hillenbrand, Claus-Dieter
Kuhn, Gerhard
Larter, Robert D.
Graham, Alastair G. C.
Ehrmann, Werner
Moreton, Steven G.
Forwick, Matthias
Deglacial History of the West Antarctic Ice Sheet in the Western Amundsen Sea Embayment
topic_facet West Antarctic Ice Sheet (WAIS)
Last Glacial Maximum (LGM)
Amundsen sea
Dating
Deglaciation
Reverse slope
Life Sciences
description The Amundsen Sea Embayment (ASE) drains approximately 35% of the West Antarctic Ice Sheet (WAIS) and is one of the most rapidly changing parts of the cryosphere. In order to predict future ice sheet behaviour, modellers require long-term records of ice-sheet melting to constrain and build confidence in their simulations. Here, we present detailed marine geological and radiocarbon data along three palaeo-ice stream tributary troughs in the western ASE to establish vital information on the timing of deglaciation of the WAIS since the Last Glacial Maximum (LGM). We have undertaken multi-proxy analyses of the cores (core description, shear strength, x-radiographs, magnetic susceptibility, wet bulk density, total organic carbon/nitrogen, carbonate content and clay mineral analyses) in order to: (1) characterise the sedimentological facies and depositional environments; and (2) identify the horizon(s) in each core that would yield the most reliable age for deglaciation. In accordance with previous studies we identify three key facies, which offer the most reliable stratigraphies for dating deglaciation by recording the transition from a grounded ice sheet to open marine environments. These facies are: i) subglacial, ii) proximal grounding line, and iii) seasonal open marine. In addition, we incorporate ages from other facies (e.g., glaciomarine diamictons deposited at some distance from the grounding line, such as glaciogenic debris flows and iceberg-rafted diamictons and turbates) into our deglacial model. In total, we have dated 78 samples (mainly the acid insoluble organic (AIO) fraction, but also calcareous foraminifers), which include 63 downcore and 15 surface samples. Through careful sample selection prior to dating, we have established a robust deglacial chronology for this sector of the WAIS. Our data show that deglaciation of the western ASE was probably underway as early as 22,351 calibrated years before present (cal yr BP), reaching the mid-shelf by 13,837 cal yr BP and the inner shelf to within c.10–12 km of the present ice shelf front between 12,618 and 10,072 cal yr BP. The deglacial steps in the western ASE broadly coincide with the rapid rises in sea-level associated with global meltwater pulses 1a and 1b, although given the potential dating uncertainty, additional, more precise ages are required before these findings can be fully substantiated. Finally, we show that the rate of ice-sheet retreat increased across the deep (up to1600 m) basins of the inner shelf, highlighting the importance of reverse slope and pinning points in accelerated phases of deglaciation.
format Article in Journal/Newspaper
author Smith, James A.
Hillenbrand, Claus-Dieter
Kuhn, Gerhard
Larter, Robert D.
Graham, Alastair G. C.
Ehrmann, Werner
Moreton, Steven G.
Forwick, Matthias
author_facet Smith, James A.
Hillenbrand, Claus-Dieter
Kuhn, Gerhard
Larter, Robert D.
Graham, Alastair G. C.
Ehrmann, Werner
Moreton, Steven G.
Forwick, Matthias
author_sort Smith, James A.
title Deglacial History of the West Antarctic Ice Sheet in the Western Amundsen Sea Embayment
title_short Deglacial History of the West Antarctic Ice Sheet in the Western Amundsen Sea Embayment
title_full Deglacial History of the West Antarctic Ice Sheet in the Western Amundsen Sea Embayment
title_fullStr Deglacial History of the West Antarctic Ice Sheet in the Western Amundsen Sea Embayment
title_full_unstemmed Deglacial History of the West Antarctic Ice Sheet in the Western Amundsen Sea Embayment
title_sort deglacial history of the west antarctic ice sheet in the western amundsen sea embayment
publisher Digital Commons @ University of South Florida
publishDate 2011
url https://digitalcommons.usf.edu/msc_facpub/1528
https://doi.org/10.1016/j.quascirev.2010.11.020
geographic Antarctic
Amundsen Sea
West Antarctic Ice Sheet
geographic_facet Antarctic
Amundsen Sea
West Antarctic Ice Sheet
genre Amundsen Sea
Antarc*
Antarctic
Ice Sheet
Ice Shelf
Iceberg*
genre_facet Amundsen Sea
Antarc*
Antarctic
Ice Sheet
Ice Shelf
Iceberg*
op_source Marine Science Faculty Publications
op_relation https://digitalcommons.usf.edu/msc_facpub/1528
https://doi.org/10.1016/j.quascirev.2010.11.020
op_doi https://doi.org/10.1016/j.quascirev.2010.11.020
container_title Quaternary Science Reviews
container_volume 30
container_issue 5-6
container_start_page 488
op_container_end_page 505
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