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Subglacial hydrology and the formation of ice streams

Antarctic ice streams are associated with pressurized subglacial meltwater but the role this water plays in the dynamics of the streams is not known. To address this, we present a model of subglacial water flow below ice sheets, and particularly below ice streams. The base-level flow is fed by subgl...

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Published in:	Proceedings of the Royal Society. A, Mathematical, physical, and engineering sciences Mathematical, physical, and engineering sciences, 2014-01, Vol.470 (2161), p.1-22
Main Authors:	Kyrke-Smith, T. M., Katz, R. F., Fowler, A. C.
Format:	Article
Language:	English
Subjects:	Film water Flow velocity Glaciers Ice Ice sheets Ice streams Sliding Water conservation Water depth Water pressure
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container_title	Proceedings of the Royal Society. A, Mathematical, physical, and engineering sciences
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creator	Kyrke-Smith, T. M. Katz, R. F. Fowler, A. C.
description	Antarctic ice streams are associated with pressurized subglacial meltwater but the role this water plays in the dynamics of the streams is not known. To address this, we present a model of subglacial water flow below ice sheets, and particularly below ice streams. The base-level flow is fed by subglacial melting and is presumed to take the form of a rough-bedded film, in which the ice is supported by larger clasts, but there is a millimetric water film which submerges the smaller particles. A model for the film is given by two coupled partial differential equations, representing mass conservation of water and ice closure. We assume that there is no sediment transport and solve for water film depth and effective pressure. This is coupled to a vertically integrated, higher order model for ice-sheet dynamics. If there is a sufficiently small amount of meltwater produced (e.g. if ice flux is low), the distributed film and ice sheet are stable, whereas for larger amounts of melt the ice–water system can become unstable, and ice streams form spontaneously as a consequence. We show that this can be explained in terms of a multi-valued sliding law, which arises from a simplified, one-dimensional analysis of the coupled model.
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C.</creator><creatorcontrib>Kyrke-Smith, T. M. ; Katz, R. F. ; Fowler, A. C.</creatorcontrib><description>Antarctic ice streams are associated with pressurized subglacial meltwater but the role this water plays in the dynamics of the streams is not known. To address this, we present a model of subglacial water flow below ice sheets, and particularly below ice streams. The base-level flow is fed by subglacial melting and is presumed to take the form of a rough-bedded film, in which the ice is supported by larger clasts, but there is a millimetric water film which submerges the smaller particles. A model for the film is given by two coupled partial differential equations, representing mass conservation of water and ice closure. We assume that there is no sediment transport and solve for water film depth and effective pressure. This is coupled to a vertically integrated, higher order model for ice-sheet dynamics. If there is a sufficiently small amount of meltwater produced (e.g. if ice flux is low), the distributed film and ice sheet are stable, whereas for larger amounts of melt the ice–water system can become unstable, and ice streams form spontaneously as a consequence. We show that this can be explained in terms of a multi-valued sliding law, which arises from a simplified, one-dimensional analysis of the coupled model.</description><identifier>ISSN: 1364-5021</identifier><language>eng</language><publisher>Royal Society</publisher><subject>Film water ; Flow velocity ; Glaciers ; Ice ; Ice sheets ; Ice streams ; Sliding ; Water conservation ; Water depth ; Water pressure</subject><ispartof>Proceedings of the Royal Society. 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We show that this can be explained in terms of a multi-valued sliding law, which arises from a simplified, one-dimensional analysis of the coupled model.</description><subject>Film water</subject><subject>Flow velocity</subject><subject>Glaciers</subject><subject>Ice</subject><subject>Ice sheets</subject><subject>Ice streams</subject><subject>Sliding</subject><subject>Water conservation</subject><subject>Water depth</subject><subject>Water pressure</subject><issn>1364-5021</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2014</creationdate><recordtype>article</recordtype><sourceid/><recordid>eNpjYeA0NDYz0TU1MDLkYOAqLs4yMDCwNLUw52QwDS5NSs9JTM5MzFHIqEwpys_JT69USMxLUSjJSFVIyy_KTSzJzM9TyE9TyExOVSguKUpNzC3mYWBNS8wpTuWF0twMsm6uIc4eulnFJflF8QVFmbmJRZXxRiamBuaWFsbGhOQBu7owLw</recordid><startdate>20140108</startdate><enddate>20140108</enddate><creator>Kyrke-Smith, T. M.</creator><creator>Katz, R. F.</creator><creator>Fowler, A. 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The base-level flow is fed by subglacial melting and is presumed to take the form of a rough-bedded film, in which the ice is supported by larger clasts, but there is a millimetric water film which submerges the smaller particles. A model for the film is given by two coupled partial differential equations, representing mass conservation of water and ice closure. We assume that there is no sediment transport and solve for water film depth and effective pressure. This is coupled to a vertically integrated, higher order model for ice-sheet dynamics. If there is a sufficiently small amount of meltwater produced (e.g. if ice flux is low), the distributed film and ice sheet are stable, whereas for larger amounts of melt the ice–water system can become unstable, and ice streams form spontaneously as a consequence. We show that this can be explained in terms of a multi-valued sliding law, which arises from a simplified, one-dimensional analysis of the coupled model.</abstract><pub>Royal Society</pub></addata></record>
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source	JSTOR Archival Journals and Primary Sources Collection; Royal Society Publishing Jisc Collections Royal Society Journals Read & Publish Transitional Agreement 2025 (reading list)
subjects	Film water Flow velocity Glaciers Ice Ice sheets Ice streams Sliding Water conservation Water depth Water pressure
title	Subglacial hydrology and the formation of ice streams
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