Inland thinning of Byrd Glacier, Antarctica, during Ross Ice Shelf formation

Abstract Geomorphological records of past ice sheet change offer the opportunity to examine their centennial‐scale response to changing boundary conditions, which are not adequately captured in the satellite record. Here, we present the first reconstruction of ice surface lowering at Byrd Glacier, t...

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Published in:	Earth Surface Processes and Landforms
Main Authors:	Stutz, Jamey, Eaves, Shaun, Norton, Kevin, Wilcken, Klaus M., Moore, Claudia, McKay, Rob, Lowry, Dan, Licht, Kathy, Johnson, Katelyn
Other Authors:	Antarctic Climate and Ecosystems Cooperative Research Centre, Australian Institute of Nuclear Science and Engineering, Ministry for Business Innovation and Employment
Format:	Article in Journal/Newspaper
Language:	English
Published:	Wiley 2023
Subjects:	Antarc* Antarctica Byrd Glacier Ice Sheet Ice Shelf Ross Ice Shelf
Online Access:	http://dx.doi.org/10.1002/esp.5701 https://onlinelibrary.wiley.com/doi/pdf/10.1002/esp.5701

id	crwiley:10.1002/esp.5701
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spelling	crwiley:10.1002/esp.5701 2024-09-15T17:45:45+00:00 Inland thinning of Byrd Glacier, Antarctica, during Ross Ice Shelf formation Stutz, Jamey Eaves, Shaun Norton, Kevin Wilcken, Klaus M. Moore, Claudia McKay, Rob Lowry, Dan Licht, Kathy Johnson, Katelyn Antarctic Climate and Ecosystems Cooperative Research Centre Australian Institute of Nuclear Science and Engineering Ministry for Business Innovation and Employment 2023 http://dx.doi.org/10.1002/esp.5701 https://onlinelibrary.wiley.com/doi/pdf/10.1002/esp.5701 en eng Wiley http://creativecommons.org/licenses/by-nc/4.0/ Earth Surface Processes and Landforms volume 48, issue 15, page 3363-3380 ISSN 0197-9337 1096-9837 journal-article 2023 crwiley https://doi.org/10.1002/esp.5701 2024-07-04T04:29:50Z Abstract Geomorphological records of past ice sheet change offer the opportunity to examine their centennial‐scale response to changing boundary conditions, which are not adequately captured in the satellite record. Here, we present the first reconstruction of ice surface lowering at Byrd Glacier, the largest outlet glacier of the Transantarctic Mountains. Using surface exposure ages from glacial erratic cobbles collected in two vertical transects along the Lonewolf Nunataks, we find the initial emergence of this set of nunataks occurred at ~15 ka, with a rapid pulse of thinning at ~8 ka. We compare our glacier thinning profiles with modelled ice sheet thickness and grounding line histories from two model ensembles to identify key processes responsible for ice sheet change. All model runs from the two ensembles predict grounding line retreat and inland thinning to occur in one rapid step from Last Glacial Maximum to present, in line with marine geology records, our exposure age data and derived glacier thinning rates. Experiments best matching the glacial thickness constraints, reconstructed from the surface exposure data, have faster basal sliding (i.e., promote greater sliding rates resulting in thinner ice). However, experiments best matching the timing and rapid rate of ice thinning derived from the same surface exposure data have higher basal friction. This apparent change in the modelled basal sliding regime, from when the ice surface is at maximum thickness, to the rapid thinning at ~8 ka, occurs as the grounding line retreats towards the Byrd Glacier and Ross Ice Shelf forms during the Holocene. This past context has implications for the stability of the modern grounding line of Byrd Glacier, which is characterised by high basal melt rates at the terminus—a process that has the potential to propagate glacier thinning far inland, impacting the overall (in)stability of the Byrd Glacier and Ross Ice Shelf. Article in Journal/Newspaper Antarc* Antarctica Byrd Glacier Ice Sheet Ice Shelf Ross Ice Shelf Wiley Online Library Earth Surface Processes and Landforms
institution	Open Polar
collection	Wiley Online Library
op_collection_id	crwiley
language	English
description	Abstract Geomorphological records of past ice sheet change offer the opportunity to examine their centennial‐scale response to changing boundary conditions, which are not adequately captured in the satellite record. Here, we present the first reconstruction of ice surface lowering at Byrd Glacier, the largest outlet glacier of the Transantarctic Mountains. Using surface exposure ages from glacial erratic cobbles collected in two vertical transects along the Lonewolf Nunataks, we find the initial emergence of this set of nunataks occurred at ~15 ka, with a rapid pulse of thinning at ~8 ka. We compare our glacier thinning profiles with modelled ice sheet thickness and grounding line histories from two model ensembles to identify key processes responsible for ice sheet change. All model runs from the two ensembles predict grounding line retreat and inland thinning to occur in one rapid step from Last Glacial Maximum to present, in line with marine geology records, our exposure age data and derived glacier thinning rates. Experiments best matching the glacial thickness constraints, reconstructed from the surface exposure data, have faster basal sliding (i.e., promote greater sliding rates resulting in thinner ice). However, experiments best matching the timing and rapid rate of ice thinning derived from the same surface exposure data have higher basal friction. This apparent change in the modelled basal sliding regime, from when the ice surface is at maximum thickness, to the rapid thinning at ~8 ka, occurs as the grounding line retreats towards the Byrd Glacier and Ross Ice Shelf forms during the Holocene. This past context has implications for the stability of the modern grounding line of Byrd Glacier, which is characterised by high basal melt rates at the terminus—a process that has the potential to propagate glacier thinning far inland, impacting the overall (in)stability of the Byrd Glacier and Ross Ice Shelf.
author2	Antarctic Climate and Ecosystems Cooperative Research Centre Australian Institute of Nuclear Science and Engineering Ministry for Business Innovation and Employment
format	Article in Journal/Newspaper
author	Stutz, Jamey Eaves, Shaun Norton, Kevin Wilcken, Klaus M. Moore, Claudia McKay, Rob Lowry, Dan Licht, Kathy Johnson, Katelyn
spellingShingle	Stutz, Jamey Eaves, Shaun Norton, Kevin Wilcken, Klaus M. Moore, Claudia McKay, Rob Lowry, Dan Licht, Kathy Johnson, Katelyn Inland thinning of Byrd Glacier, Antarctica, during Ross Ice Shelf formation
author_facet	Stutz, Jamey Eaves, Shaun Norton, Kevin Wilcken, Klaus M. Moore, Claudia McKay, Rob Lowry, Dan Licht, Kathy Johnson, Katelyn
author_sort	Stutz, Jamey
title	Inland thinning of Byrd Glacier, Antarctica, during Ross Ice Shelf formation
title_short	Inland thinning of Byrd Glacier, Antarctica, during Ross Ice Shelf formation
title_full	Inland thinning of Byrd Glacier, Antarctica, during Ross Ice Shelf formation
title_fullStr	Inland thinning of Byrd Glacier, Antarctica, during Ross Ice Shelf formation
title_full_unstemmed	Inland thinning of Byrd Glacier, Antarctica, during Ross Ice Shelf formation
title_sort	inland thinning of byrd glacier, antarctica, during ross ice shelf formation
publisher	Wiley
publishDate	2023
url	http://dx.doi.org/10.1002/esp.5701 https://onlinelibrary.wiley.com/doi/pdf/10.1002/esp.5701
genre	Antarc* Antarctica Byrd Glacier Ice Sheet Ice Shelf Ross Ice Shelf
genre_facet	Antarc* Antarctica Byrd Glacier Ice Sheet Ice Shelf Ross Ice Shelf
op_source	Earth Surface Processes and Landforms volume 48, issue 15, page 3363-3380 ISSN 0197-9337 1096-9837
op_rights	http://creativecommons.org/licenses/by-nc/4.0/
op_doi	https://doi.org/10.1002/esp.5701
container_title	Earth Surface Processes and Landforms
_version_	1810493654347808768

Inland thinning of Byrd Glacier, Antarctica, during Ross Ice Shelf formation

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