Thermo-Mechanical Regime of the Greenland Ice Sheet and Erosion Potential of the Crystalline Bedrock

Past glaciation is known to have caused a substantial morphological change to high latitude regions of the northern hemisphere. In the assessment of the long-term performance of deep geological repositories for radioactive wastes, future glaciation is a critical factor to take into consideration. Th...

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Bibliographic Details
Published in:Minerals
Main Authors: Zhenze Li, Thanh Son Nguyen
Format: Text
Language:English
Published: Multidisciplinary Digital Publishing Institute 2021
Subjects:
Greenland Analogue Project
glaciation
erosion
rheology
ice sheet
TM coupling
Greenland
glacier
Ice Sheet
Online Access:https://doi.org/10.3390/min11020120
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spelling ftmdpi:oai:mdpi.com:/2075-163X/11/2/120/ 2023-08-20T04:06:41+02:00 Thermo-Mechanical Regime of the Greenland Ice Sheet and Erosion Potential of the Crystalline Bedrock Zhenze Li Thanh Son Nguyen agris 2021-01-26 application/pdf https://doi.org/10.3390/min11020120 EN eng Multidisciplinary Digital Publishing Institute Environmental Mineralogy and Biogeochemistry https://dx.doi.org/10.3390/min11020120 https://creativecommons.org/licenses/by/4.0/ Minerals; Volume 11; Issue 2; Pages: 120 Greenland Analogue Project glaciation erosion rheology ice sheet TM coupling Text 2021 ftmdpi https://doi.org/10.3390/min11020120 2023-08-01T00:56:18Z Past glaciation is known to have caused a substantial morphological change to high latitude regions of the northern hemisphere. In the assessment of the long-term performance of deep geological repositories for radioactive wastes, future glaciation is a critical factor to take into consideration. This study develops a thermal-mechanical model to investigate ice sheet thermal evolution and the impact on bedrock erosion. The model is based on comprehensive field data resulting from international collaborative research on the Greenland Analogue Project. The ice sheet model considers surface energy balance and basal heat flux, as well as the temperature-dependent flow of ice that follows Glen’s law. The ice-bedrock interface is treated with a mechanical contact model, which solves the relative velocity and predicts the abrasional erosion and meltwater flow erosion. The numerical model is calibrated with measured temperature profiles and surface velocities at different locations across the glacier cross-section. The erosion rate is substantially larger near the glacier edge, where channel flow erosion becomes predominant. The abrasional erosion rate is averaged at 0.006 mm/a, and peaks at regions near the ridge divide. The mean meltwater flow erosion rate in the study area is estimated to be about 0.12 mm/a for the melted base region. Text glacier Greenland Ice Sheet MDPI Open Access Publishing Greenland Minerals 11 2 120
institution Open Polar
collection MDPI Open Access Publishing
op_collection_id ftmdpi
language English
topic Greenland Analogue Project
glaciation
erosion
rheology
ice sheet
TM coupling
spellingShingle Greenland Analogue Project
glaciation
erosion
rheology
ice sheet
TM coupling
Zhenze Li
Thanh Son Nguyen
Thermo-Mechanical Regime of the Greenland Ice Sheet and Erosion Potential of the Crystalline Bedrock
topic_facet Greenland Analogue Project
glaciation
erosion
rheology
ice sheet
TM coupling
description Past glaciation is known to have caused a substantial morphological change to high latitude regions of the northern hemisphere. In the assessment of the long-term performance of deep geological repositories for radioactive wastes, future glaciation is a critical factor to take into consideration. This study develops a thermal-mechanical model to investigate ice sheet thermal evolution and the impact on bedrock erosion. The model is based on comprehensive field data resulting from international collaborative research on the Greenland Analogue Project. The ice sheet model considers surface energy balance and basal heat flux, as well as the temperature-dependent flow of ice that follows Glen’s law. The ice-bedrock interface is treated with a mechanical contact model, which solves the relative velocity and predicts the abrasional erosion and meltwater flow erosion. The numerical model is calibrated with measured temperature profiles and surface velocities at different locations across the glacier cross-section. The erosion rate is substantially larger near the glacier edge, where channel flow erosion becomes predominant. The abrasional erosion rate is averaged at 0.006 mm/a, and peaks at regions near the ridge divide. The mean meltwater flow erosion rate in the study area is estimated to be about 0.12 mm/a for the melted base region.
format Text
author Zhenze Li
Thanh Son Nguyen
author_facet Zhenze Li
Thanh Son Nguyen
author_sort Zhenze Li
title Thermo-Mechanical Regime of the Greenland Ice Sheet and Erosion Potential of the Crystalline Bedrock
title_short Thermo-Mechanical Regime of the Greenland Ice Sheet and Erosion Potential of the Crystalline Bedrock
title_full Thermo-Mechanical Regime of the Greenland Ice Sheet and Erosion Potential of the Crystalline Bedrock
title_fullStr Thermo-Mechanical Regime of the Greenland Ice Sheet and Erosion Potential of the Crystalline Bedrock
title_full_unstemmed Thermo-Mechanical Regime of the Greenland Ice Sheet and Erosion Potential of the Crystalline Bedrock
title_sort thermo-mechanical regime of the greenland ice sheet and erosion potential of the crystalline bedrock
publisher Multidisciplinary Digital Publishing Institute
publishDate 2021
url https://doi.org/10.3390/min11020120
op_coverage agris
geographic Greenland
geographic_facet Greenland
genre glacier
Greenland
Ice Sheet
genre_facet glacier
Greenland
Ice Sheet
op_source Minerals; Volume 11; Issue 2; Pages: 120
op_relation Environmental Mineralogy and Biogeochemistry
https://dx.doi.org/10.3390/min11020120
op_rights https://creativecommons.org/licenses/by/4.0/
op_doi https://doi.org/10.3390/min11020120
container_title Minerals
container_volume 11
container_issue 2
container_start_page 120
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