The Effect of Firn-Aquifer Drainage on the Greenland Subglacial System or Subglacial Efficiency and Storage Modified by the Temporal Pattern of High-Elevation Meltwater Input
Ice flow in marginal region of the Greenland Ice Sheet dynamically responds to summer melting as surface meltwater is routed through the supraglacial hydrologic system to the bed of the ice sheet via crevasses and moulins. Given the expected increases in surface melt production and extent, and the p...
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2017
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| Online Access: | http://hdl.handle.net/2060/20180000626 |
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ftnasantrs:oai:casi.ntrs.nasa.gov:20180000626 |
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ftnasantrs:oai:casi.ntrs.nasa.gov:20180000626 2023-05-15T16:21:31+02:00 The Effect of Firn-Aquifer Drainage on the Greenland Subglacial System or Subglacial Efficiency and Storage Modified by the Temporal Pattern of High-Elevation Meltwater Input Poinar, Kristin Dow, Christine F. Andrews, Lauren C. Nowicki, Sophie M. Unclassified, Unlimited, Publicly available December 11, 2017 application/pdf http://hdl.handle.net/2060/20180000626 unknown Document ID: 20180000626 http://hdl.handle.net/2060/20180000626 Copyright, Portions of the document may include copyright protected material CASI Geophysics C22A-03 GSFC-E-DAA-TN50451 2017 AGU Fall Meeting; 11-15 Dec. 2017; New Orleans, LA; United States 2017 ftnasantrs 2019-07-20T23:20:44Z Ice flow in marginal region of the Greenland Ice Sheet dynamically responds to summer melting as surface meltwater is routed through the supraglacial hydrologic system to the bed of the ice sheet via crevasses and moulins. Given the expected increases in surface melt production and extent, and the potential for high elevation surface-to-bed connections, it is imperative to understand how meltwater delivered to the bed from different high-elevation supraglacial storage features affects the evolution of the subglacial hydrologic system and associated ice dynamics. Here, we use the two-dimensional subglacial hydrologic model, GLaDS, which includes distributed and channelized water flow, to test how the subglacial system of an idealized outlet glacier responds to cases of high-elevation firn-aquifer-type and supraglacial-lake-type englacial drainage over the course of 5 years. Model outputs driven by these high elevation drainage types are compared to steady-state model results, where the subglacial system only receives the 1980- 2016 mean MERRA-2 runoff via low-elevation moulins. Across all experiments, the subglacial hydrologic system displays inter-annual memory, resulting in multiyear declines in subglacial pressure during the onset of seasonal melting and growth of subglacial channels. The gradual addition of water in firn-aquifer-type drainage scenarios resulted in small increases in subglacial water storage but limited changes in subglacial efficiency and channelization. Rapid, supraglacial- lake-type drainage resulted in short-term local increases in subglacial water pressure and storage, which gave way to spatially extensive decreases in subglacial pressure and downstream channelization. These preliminary results suggest that the character of high-elevation englacial drainage can have a strong, and possibly outsized, control on subglacial efficiency throughout the ablation zone. Therefore, understanding both how high elevation meltwater is stored supraglacially and the probability of crevassing at high elevations will play an important role in how the subglacial system, proglacial discharge and ice motion will respond to future increases in surface melt production and runoff. Other/Unknown Material glacier Greenland Ice Sheet NASA Technical Reports Server (NTRS) Greenland Merra ENVELOPE(12.615,12.615,65.816,65.816) |
| institution |
Open Polar |
| collection |
NASA Technical Reports Server (NTRS) |
| op_collection_id |
ftnasantrs |
| language |
unknown |
| topic |
Geophysics |
| spellingShingle |
Geophysics Poinar, Kristin Dow, Christine F. Andrews, Lauren C. Nowicki, Sophie M. The Effect of Firn-Aquifer Drainage on the Greenland Subglacial System or Subglacial Efficiency and Storage Modified by the Temporal Pattern of High-Elevation Meltwater Input |
| topic_facet |
Geophysics |
| description |
Ice flow in marginal region of the Greenland Ice Sheet dynamically responds to summer melting as surface meltwater is routed through the supraglacial hydrologic system to the bed of the ice sheet via crevasses and moulins. Given the expected increases in surface melt production and extent, and the potential for high elevation surface-to-bed connections, it is imperative to understand how meltwater delivered to the bed from different high-elevation supraglacial storage features affects the evolution of the subglacial hydrologic system and associated ice dynamics. Here, we use the two-dimensional subglacial hydrologic model, GLaDS, which includes distributed and channelized water flow, to test how the subglacial system of an idealized outlet glacier responds to cases of high-elevation firn-aquifer-type and supraglacial-lake-type englacial drainage over the course of 5 years. Model outputs driven by these high elevation drainage types are compared to steady-state model results, where the subglacial system only receives the 1980- 2016 mean MERRA-2 runoff via low-elevation moulins. Across all experiments, the subglacial hydrologic system displays inter-annual memory, resulting in multiyear declines in subglacial pressure during the onset of seasonal melting and growth of subglacial channels. The gradual addition of water in firn-aquifer-type drainage scenarios resulted in small increases in subglacial water storage but limited changes in subglacial efficiency and channelization. Rapid, supraglacial- lake-type drainage resulted in short-term local increases in subglacial water pressure and storage, which gave way to spatially extensive decreases in subglacial pressure and downstream channelization. These preliminary results suggest that the character of high-elevation englacial drainage can have a strong, and possibly outsized, control on subglacial efficiency throughout the ablation zone. Therefore, understanding both how high elevation meltwater is stored supraglacially and the probability of crevassing at high elevations will play an important role in how the subglacial system, proglacial discharge and ice motion will respond to future increases in surface melt production and runoff. |
| format |
Other/Unknown Material |
| author |
Poinar, Kristin Dow, Christine F. Andrews, Lauren C. Nowicki, Sophie M. |
| author_facet |
Poinar, Kristin Dow, Christine F. Andrews, Lauren C. Nowicki, Sophie M. |
| author_sort |
Poinar, Kristin |
| title |
The Effect of Firn-Aquifer Drainage on the Greenland Subglacial System or Subglacial Efficiency and Storage Modified by the Temporal Pattern of High-Elevation Meltwater Input |
| title_short |
The Effect of Firn-Aquifer Drainage on the Greenland Subglacial System or Subglacial Efficiency and Storage Modified by the Temporal Pattern of High-Elevation Meltwater Input |
| title_full |
The Effect of Firn-Aquifer Drainage on the Greenland Subglacial System or Subglacial Efficiency and Storage Modified by the Temporal Pattern of High-Elevation Meltwater Input |
| title_fullStr |
The Effect of Firn-Aquifer Drainage on the Greenland Subglacial System or Subglacial Efficiency and Storage Modified by the Temporal Pattern of High-Elevation Meltwater Input |
| title_full_unstemmed |
The Effect of Firn-Aquifer Drainage on the Greenland Subglacial System or Subglacial Efficiency and Storage Modified by the Temporal Pattern of High-Elevation Meltwater Input |
| title_sort |
effect of firn-aquifer drainage on the greenland subglacial system or subglacial efficiency and storage modified by the temporal pattern of high-elevation meltwater input |
| publishDate |
2017 |
| url |
http://hdl.handle.net/2060/20180000626 |
| op_coverage |
Unclassified, Unlimited, Publicly available |
| long_lat |
ENVELOPE(12.615,12.615,65.816,65.816) |
| geographic |
Greenland Merra |
| geographic_facet |
Greenland Merra |
| genre |
glacier Greenland Ice Sheet |
| genre_facet |
glacier Greenland Ice Sheet |
| op_source |
CASI |
| op_relation |
Document ID: 20180000626 http://hdl.handle.net/2060/20180000626 |
| op_rights |
Copyright, Portions of the document may include copyright protected material |
| _version_ |
1766009522599493632 |