Evidence for floatation or near floatation in the mouth of Kamb Ice Stream, West Antarctica, prior to stagnation
Ice‐penetrating radar profiles reveal distinctive internal structure within the flat ice terrains that bound the lower reaches of the now stagnant Kamb Ice Stream, West Antarctica; slightly warped but continuous upper layers overlie extensive deep line diffractors located at a uniform depth several...
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| Published in: | Journal of Geophysical Research - Earth Surface Vol. 111; no. F1; pp. F01005 - n/a |
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| Main Authors: | , , , |
| Format: | Journal Article |
| Language: | English |
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Washington, DC
American Geophysical Union
01-03-2006
Blackwell Publishing Ltd |
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| Abstract | Ice‐penetrating radar profiles reveal distinctive internal structure within the flat ice terrains that bound the lower reaches of the now stagnant Kamb Ice Stream, West Antarctica; slightly warped but continuous upper layers overlie extensive deep line diffractors located at a uniform depth several hundreds of meters above the bed. On the basis of their orientation and morphology we interpret the line diffractors to be the tips of basal crevasses. At the boundary between these terrains and the inter–ice stream ridges, internal layers are strongly downwarped, and the deepest layers are truncated at the bed. Results from simple kinematic ice flow modeling indicate that the observed layer pattern requires a cumulative basal melt of 120–350 m over a time period that is less than 300 years. Fields of basal crevasses are typically observed in ice shelves; however, isolated basal crevasses can also be found in grounded ice when the subglacial water pressure is close to overburden. On the basis of the presence of these crevasses we argue that these terrains were once floating or near floating in the past. We combine model results with estimates of recent ice thickness change to suggest that floatation was transitory and the region may have become fully grounded roughly 200 years prior to stagnation of Kamb Ice Stream. |
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| AbstractList | Ice‐penetrating radar profiles reveal distinctive internal structure within the flat ice terrains that bound the lower reaches of the now stagnant Kamb Ice Stream, West Antarctica; slightly warped but continuous upper layers overlie extensive deep line diffractors located at a uniform depth several hundreds of meters above the bed. On the basis of their orientation and morphology we interpret the line diffractors to be the tips of basal crevasses. At the boundary between these terrains and the inter–ice stream ridges, internal layers are strongly downwarped, and the deepest layers are truncated at the bed. Results from simple kinematic ice flow modeling indicate that the observed layer pattern requires a cumulative basal melt of 120–350 m over a time period that is less than 300 years. Fields of basal crevasses are typically observed in ice shelves; however, isolated basal crevasses can also be found in grounded ice when the subglacial water pressure is close to overburden. On the basis of the presence of these crevasses we argue that these terrains were once floating or near floating in the past. We combine model results with estimates of recent ice thickness change to suggest that floatation was transitory and the region may have become fully grounded roughly 200 years prior to stagnation of Kamb Ice Stream. |
| Author | Conway, H. Raymond, C. F. Catania, G. A. Scambos, T. A. |
| Author_xml | – sequence: 1 givenname: G. A. surname: Catania fullname: Catania, G. A. email: gcatania@utig.ig.utexas.edu organization: Institute for Geophysics, University of Texas at Austin, Texas, Austin, USA – sequence: 2 givenname: H. surname: Conway fullname: Conway, H. organization: Department of Earth and Space Sciences, University of Washington, Washington, Seattle, USA – sequence: 3 givenname: C. F. surname: Raymond fullname: Raymond, C. F. organization: Department of Earth and Space Sciences, University of Washington, Washington, Seattle, USA – sequence: 4 givenname: T. A. surname: Scambos fullname: Scambos, T. A. organization: National Snow and Ice Data Center, University of Colorado, Colorado, Boulder, USA |
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| Keywords | ice streams grounding line ice-penetrating radar Internal layer models orientation overburden morphology thickness kinematics water pressure Floating ice Modeling Ice stream ice shelves depth ground ice Internal structure Ice shelf polar regions melts radar methods |
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| Snippet | Ice‐penetrating radar profiles reveal distinctive internal structure within the flat ice terrains that bound the lower reaches of the now stagnant Kamb Ice... Ice-penetrating radar profiles reveal distinctive internal structure within the flat ice terrains that bound the lower reaches of the now stagnant Kamb Ice... |
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| SubjectTerms | Antarctica Cryosphere Earth sciences Earth, ocean, space Exact sciences and technology Geographic Location Glaciology grounding line Ice streams ice-penetrating radar Modeling Remote sensing |
| Title | Evidence for floatation or near floatation in the mouth of Kamb Ice Stream, West Antarctica, prior to stagnation |
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