Understanding ice-sheet dynamics using geophysical observations and numerical ice-flow models
Thesis (Ph.D.)--University of Washington, 2018 Mass loss from the world’s ice sheets is one of the largest sources of uncertainty in sea-level rise projections for the 21st century. One way to improve sea-level rise projections is to better understand the processes driving past ice-sheet mass loss....
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| Language: | English |
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2018
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| Online Access: | http://hdl.handle.net/1773/43212 |
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ftunivwashington:oai:digital.lib.washington.edu:1773/43212 2023-05-15T13:47:49+02:00 Understanding ice-sheet dynamics using geophysical observations and numerical ice-flow models Kehrl, Laura Joughin, Ian R 2018 application/pdf http://hdl.handle.net/1773/43212 en_US eng Kehrl_washington_0250E_19396.pdf http://hdl.handle.net/1773/43212 CC BY Glaciology Ice flow Ice-penetrating radar Ice sheets Numerical modeling Satellite remote sensing Geophysics Remote sensing Climate change Earth and space sciences Thesis 2018 ftunivwashington 2023-03-12T18:58:59Z Thesis (Ph.D.)--University of Washington, 2018 Mass loss from the world’s ice sheets is one of the largest sources of uncertainty in sea-level rise projections for the 21st century. One way to improve sea-level rise projections is to better understand the processes driving past ice-sheet mass loss. This dissertation investigates past changes in ice flow for two regions: (1) Helheim and Kangerlussuaq Glaciers, two fast-flowing tidewater glaciers in Southeast Greenland, and (2) the Allan Hills Blue Ice Area, a slow-flowing blue ice area in East Antarctica. For both regions, I constrain changes in ice-sheet dynamics using geophysical observations and interpret those changes using numerical ice-flow models. At Helheim and Kangerlussuaq, I examine seasonal and interannual variations in surface velocity, elevation, and terminus position from 2001 to 2016. I show that glacier dynamics depend on the extent of floating ice near the terminus. Helheim’s grounded terminus calved small, nontabular icebergs, while Kangerlussuaq’s floating ice tongue calved large, tabular icebergs. Furthermore, terminus-driven, seasonal speedups and dynamic thinning were generally larger at Helheim than at Kangerlussuaq, likely due to its grounded rather than floating ice tongue. To interpret the observed changes at Helheim and Kangerlussuaq, I use inverse methods to investigate changes in basal conditions under the two glaciers. The basal shear stress under Helheim and Kangerlussuaq decreased or remained relatively constant during terminus-driven speedup events, suggesting that changes in the stress balance were generally supported outside of the region of fast flow. Finally, I use the inferred basal shear stresses to help constrain the form of the basal sliding law. At the Allan Hills Blue Ice Area, I combine ice-penetrating radar data, an ice-flow model, and age constraints to determine a potential site to drill a million-year-old ice core. I also show that thickness anomalies in the englacial stratigraphy suggest that glacier velocity ... Thesis Antarc* Antarctica East Antarctica glacier Greenland ice core Ice Sheet Kangerlussuaq Tidewater University of Washington, Seattle: ResearchWorks Allan Hills ENVELOPE(159.667,159.667,-76.717,-76.717) East Antarctica Greenland Kangerlussuaq ENVELOPE(-55.633,-55.633,72.633,72.633) |
| institution |
Open Polar |
| collection |
University of Washington, Seattle: ResearchWorks |
| op_collection_id |
ftunivwashington |
| language |
English |
| topic |
Glaciology Ice flow Ice-penetrating radar Ice sheets Numerical modeling Satellite remote sensing Geophysics Remote sensing Climate change Earth and space sciences |
| spellingShingle |
Glaciology Ice flow Ice-penetrating radar Ice sheets Numerical modeling Satellite remote sensing Geophysics Remote sensing Climate change Earth and space sciences Kehrl, Laura Understanding ice-sheet dynamics using geophysical observations and numerical ice-flow models |
| topic_facet |
Glaciology Ice flow Ice-penetrating radar Ice sheets Numerical modeling Satellite remote sensing Geophysics Remote sensing Climate change Earth and space sciences |
| description |
Thesis (Ph.D.)--University of Washington, 2018 Mass loss from the world’s ice sheets is one of the largest sources of uncertainty in sea-level rise projections for the 21st century. One way to improve sea-level rise projections is to better understand the processes driving past ice-sheet mass loss. This dissertation investigates past changes in ice flow for two regions: (1) Helheim and Kangerlussuaq Glaciers, two fast-flowing tidewater glaciers in Southeast Greenland, and (2) the Allan Hills Blue Ice Area, a slow-flowing blue ice area in East Antarctica. For both regions, I constrain changes in ice-sheet dynamics using geophysical observations and interpret those changes using numerical ice-flow models. At Helheim and Kangerlussuaq, I examine seasonal and interannual variations in surface velocity, elevation, and terminus position from 2001 to 2016. I show that glacier dynamics depend on the extent of floating ice near the terminus. Helheim’s grounded terminus calved small, nontabular icebergs, while Kangerlussuaq’s floating ice tongue calved large, tabular icebergs. Furthermore, terminus-driven, seasonal speedups and dynamic thinning were generally larger at Helheim than at Kangerlussuaq, likely due to its grounded rather than floating ice tongue. To interpret the observed changes at Helheim and Kangerlussuaq, I use inverse methods to investigate changes in basal conditions under the two glaciers. The basal shear stress under Helheim and Kangerlussuaq decreased or remained relatively constant during terminus-driven speedup events, suggesting that changes in the stress balance were generally supported outside of the region of fast flow. Finally, I use the inferred basal shear stresses to help constrain the form of the basal sliding law. At the Allan Hills Blue Ice Area, I combine ice-penetrating radar data, an ice-flow model, and age constraints to determine a potential site to drill a million-year-old ice core. I also show that thickness anomalies in the englacial stratigraphy suggest that glacier velocity ... |
| author2 |
Joughin, Ian R |
| format |
Thesis |
| author |
Kehrl, Laura |
| author_facet |
Kehrl, Laura |
| author_sort |
Kehrl, Laura |
| title |
Understanding ice-sheet dynamics using geophysical observations and numerical ice-flow models |
| title_short |
Understanding ice-sheet dynamics using geophysical observations and numerical ice-flow models |
| title_full |
Understanding ice-sheet dynamics using geophysical observations and numerical ice-flow models |
| title_fullStr |
Understanding ice-sheet dynamics using geophysical observations and numerical ice-flow models |
| title_full_unstemmed |
Understanding ice-sheet dynamics using geophysical observations and numerical ice-flow models |
| title_sort |
understanding ice-sheet dynamics using geophysical observations and numerical ice-flow models |
| publishDate |
2018 |
| url |
http://hdl.handle.net/1773/43212 |
| long_lat |
ENVELOPE(159.667,159.667,-76.717,-76.717) ENVELOPE(-55.633,-55.633,72.633,72.633) |
| geographic |
Allan Hills East Antarctica Greenland Kangerlussuaq |
| geographic_facet |
Allan Hills East Antarctica Greenland Kangerlussuaq |
| genre |
Antarc* Antarctica East Antarctica glacier Greenland ice core Ice Sheet Kangerlussuaq Tidewater |
| genre_facet |
Antarc* Antarctica East Antarctica glacier Greenland ice core Ice Sheet Kangerlussuaq Tidewater |
| op_relation |
Kehrl_washington_0250E_19396.pdf http://hdl.handle.net/1773/43212 |
| op_rights |
CC BY |
| _version_ |
1766247916577488896 |