A new methodology to simulate subglacial deformation of water saturated granular material

The dynamics of glaciers are to a large degree governed by processes operating at the ice-bed interface, and one of the primary mechanisms of glacier flow over soft unconsolidated sediments is subglacial deformation. However, it has proven difficult to constrain the mechanical response of subglacial...

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Published in:	The Cryosphere
Main Authors:	Damsgaard, Anders, Egholm, David Lundbek, Piotrowski, Jan A., Tulaczyk, Slawek, Larsen, Nicolaj Krog, Brædstrup, Christian
Format:	Article in Journal/Newspaper
Language:	English
Published:	2015
Subjects:	The Cryosphere
Online Access:	https://pure.au.dk/portal/da/publications/a-new-methodology-to-simulate-subglacial-deformation-of-water-saturated-granular-material(e366c02d-0786-4726-bb5a-ce90093919ea).html https://doi.org/10.5194/tc-9-2183-2015 http://www.the-cryosphere-discuss.net/9/3617/2015/tcd-9-3617-2015.html

id	ftuniaarhuspubl:oai:pure.atira.dk:publications/e366c02d-0786-4726-bb5a-ce90093919ea
record_format	openpolar
spelling	ftuniaarhuspubl:oai:pure.atira.dk:publications/e366c02d-0786-4726-bb5a-ce90093919ea 2023-05-15T18:32:30+02:00 A new methodology to simulate subglacial deformation of water saturated granular material Damsgaard, Anders Egholm, David Lundbek Piotrowski, Jan A. Tulaczyk, Slawek Larsen, Nicolaj Krog Brædstrup, Christian 2015-11-20 https://pure.au.dk/portal/da/publications/a-new-methodology-to-simulate-subglacial-deformation-of-water-saturated-granular-material(e366c02d-0786-4726-bb5a-ce90093919ea).html https://doi.org/10.5194/tc-9-2183-2015 http://www.the-cryosphere-discuss.net/9/3617/2015/tcd-9-3617-2015.html eng eng info:eu-repo/semantics/openAccess Damsgaard , A , Egholm , D L , Piotrowski , J A , Tulaczyk , S , Larsen , N K & Brædstrup , C 2015 , ' A new methodology to simulate subglacial deformation of water saturated granular material ' , The Cryosphere , vol. 9 , no. 6 , pp. 2183– 2200 . https://doi.org/10.5194/tc-9-2183-2015 article 2015 ftuniaarhuspubl https://doi.org/10.5194/tc-9-2183-2015 2020-10-28T23:42:59Z The dynamics of glaciers are to a large degree governed by processes operating at the ice-bed interface, and one of the primary mechanisms of glacier flow over soft unconsolidated sediments is subglacial deformation. However, it has proven difficult to constrain the mechanical response of subglacial sediment to the shear stress of an overriding glacier. In this study, we present a new methodology designed to simulate subglacial deformation using a coupled numerical model for computational experiments on grain-fluid mixtures. The granular phase is simulated on a per-grain basis by the discrete element method. The pore water is modeled as a compressible Newtonian fluid without inertia. The numerical approach allows close monitoring of the internal behavior under a range of conditions. The rheology of a water-saturated granular bed may include both plastic and rate-dependent dilatant hardening or weakening components, depending on the rate of deformation, the material state, clay mineral content, and the hydrological properties of the material. The influence of the fluid phase is negligible when relatively permeable sediment is deformed. However, by reducing the local permeability, fast deformation can cause variations in the pore-fluid pressure. The pressure variations weaken or strengthen the granular phase, and in turn influence the distribution of shear strain with depth. In permeable sediments the strain distribution is governed by the grain-size distribution and effective normal stress and is typically on the order of tens of centimeters. Significant dilatant strengthening in impermeable sediments causes deformation to focus at the hydrologically more stable ice-bed interface, and results in a very shallow cm-to-mm deformational depth. The amount of strengthening felt by the glacier depends on the hydraulic conductivity at the ice-bed interface. Grain-fluid feedbacks can cause complex material properties that vary over time, and which may be of importance for glacier stick-slip behavior. Article in Journal/Newspaper The Cryosphere Aarhus University: Research The Cryosphere 9 6 2183 2200
institution	Open Polar
collection	Aarhus University: Research
op_collection_id	ftuniaarhuspubl
language	English
description	The dynamics of glaciers are to a large degree governed by processes operating at the ice-bed interface, and one of the primary mechanisms of glacier flow over soft unconsolidated sediments is subglacial deformation. However, it has proven difficult to constrain the mechanical response of subglacial sediment to the shear stress of an overriding glacier. In this study, we present a new methodology designed to simulate subglacial deformation using a coupled numerical model for computational experiments on grain-fluid mixtures. The granular phase is simulated on a per-grain basis by the discrete element method. The pore water is modeled as a compressible Newtonian fluid without inertia. The numerical approach allows close monitoring of the internal behavior under a range of conditions. The rheology of a water-saturated granular bed may include both plastic and rate-dependent dilatant hardening or weakening components, depending on the rate of deformation, the material state, clay mineral content, and the hydrological properties of the material. The influence of the fluid phase is negligible when relatively permeable sediment is deformed. However, by reducing the local permeability, fast deformation can cause variations in the pore-fluid pressure. The pressure variations weaken or strengthen the granular phase, and in turn influence the distribution of shear strain with depth. In permeable sediments the strain distribution is governed by the grain-size distribution and effective normal stress and is typically on the order of tens of centimeters. Significant dilatant strengthening in impermeable sediments causes deformation to focus at the hydrologically more stable ice-bed interface, and results in a very shallow cm-to-mm deformational depth. The amount of strengthening felt by the glacier depends on the hydraulic conductivity at the ice-bed interface. Grain-fluid feedbacks can cause complex material properties that vary over time, and which may be of importance for glacier stick-slip behavior.
format	Article in Journal/Newspaper
author	Damsgaard, Anders Egholm, David Lundbek Piotrowski, Jan A. Tulaczyk, Slawek Larsen, Nicolaj Krog Brædstrup, Christian
spellingShingle	Damsgaard, Anders Egholm, David Lundbek Piotrowski, Jan A. Tulaczyk, Slawek Larsen, Nicolaj Krog Brædstrup, Christian A new methodology to simulate subglacial deformation of water saturated granular material
author_facet	Damsgaard, Anders Egholm, David Lundbek Piotrowski, Jan A. Tulaczyk, Slawek Larsen, Nicolaj Krog Brædstrup, Christian
author_sort	Damsgaard, Anders
title	A new methodology to simulate subglacial deformation of water saturated granular material
title_short	A new methodology to simulate subglacial deformation of water saturated granular material
title_full	A new methodology to simulate subglacial deformation of water saturated granular material
title_fullStr	A new methodology to simulate subglacial deformation of water saturated granular material
title_full_unstemmed	A new methodology to simulate subglacial deformation of water saturated granular material
title_sort	new methodology to simulate subglacial deformation of water saturated granular material
publishDate	2015
url	https://pure.au.dk/portal/da/publications/a-new-methodology-to-simulate-subglacial-deformation-of-water-saturated-granular-material(e366c02d-0786-4726-bb5a-ce90093919ea).html https://doi.org/10.5194/tc-9-2183-2015 http://www.the-cryosphere-discuss.net/9/3617/2015/tcd-9-3617-2015.html
genre	The Cryosphere
genre_facet	The Cryosphere
op_source	Damsgaard , A , Egholm , D L , Piotrowski , J A , Tulaczyk , S , Larsen , N K & Brædstrup , C 2015 , ' A new methodology to simulate subglacial deformation of water saturated granular material ' , The Cryosphere , vol. 9 , no. 6 , pp. 2183– 2200 . https://doi.org/10.5194/tc-9-2183-2015
op_rights	info:eu-repo/semantics/openAccess
op_doi	https://doi.org/10.5194/tc-9-2183-2015
container_title	The Cryosphere
container_volume	9
container_issue	6
container_start_page	2183
op_container_end_page	2200
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A new methodology to simulate subglacial deformation of water saturated granular material

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