Data supporting "Controls on Greenland moulin geometry and evolution from the Moulin Shape model"

Nearly all meltwater from glaciers and ice sheets is routed englacially through moulins. Therefore, the geometry and evolution of moulins has the potential to influence subglacial water pressure variations, ice motion, and the runoff hydrograph delivered to the ocean. We develop the Moulin Shape (Mo...

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Bibliographic Details
Main Authors: Andrews, Lauren C., Poinar, Kristin, Trunz, Celia
Format: Dataset
Language:English
Published: 2021
Subjects:
glaciology
Greenland
model data
Online Access:http://hdl.handle.net/10477/82587
id ftunivbuffalo:oai:ubir.buffalo.edu:10477/82587
record_format openpolar
spelling ftunivbuffalo:oai:ubir.buffalo.edu:10477/82587 2023-05-15T16:27:52+02:00 Data supporting "Controls on Greenland moulin geometry and evolution from the Moulin Shape model" Andrews, Lauren C. Poinar, Kristin Trunz, Celia 2021-02-03 application/mat http://hdl.handle.net/10477/82587 eng eng http://hdl.handle.net/10477/82587 glaciology Greenland model data Dataset 2021 ftunivbuffalo 2023-01-08T17:21:40Z Nearly all meltwater from glaciers and ice sheets is routed englacially through moulins. Therefore, the geometry and evolution of moulins has the potential to influence subglacial water pressure variations, ice motion, and the runoff hydrograph delivered to the ocean. We develop the Moulin Shape (MouSh) model, a time-evolving model of moulin geometry. MouSh models ice deformation around a moulin using both viscous and elastic rheologies and melting within the moulin through heat dissipation from turbulent water flow, both above and below the water line. We force MouSh with idealized and realistic surface melt inputs. Our results show that variations in surface melt change the geometry of a moulin by approximately 10% daily and over 100% seasonally. These size variations cause observable differences in moulin water storage capacity and moulin water levels compared to a static, cylindrical moulin. Our results suggest that moulins are significant storage reservoirs for meltwater, with storage capacity and water levels varying over multiple timescales. Representing moulin geometry within subglacial hydrologic models may therefore improve the representation of subglacial pressures, especially over seasonal periods or in regions where overburden pressures are high. NASA Cryosphere 80NSSC19K0054 Dataset Greenland UBIR Repository (University at Buffalo Institutional Repository) Greenland
institution Open Polar
collection UBIR Repository (University at Buffalo Institutional Repository)
op_collection_id ftunivbuffalo
language English
topic glaciology
Greenland
model data
spellingShingle glaciology
Greenland
model data
Andrews, Lauren C.
Poinar, Kristin
Trunz, Celia
Data supporting "Controls on Greenland moulin geometry and evolution from the Moulin Shape model"
topic_facet glaciology
Greenland
model data
description Nearly all meltwater from glaciers and ice sheets is routed englacially through moulins. Therefore, the geometry and evolution of moulins has the potential to influence subglacial water pressure variations, ice motion, and the runoff hydrograph delivered to the ocean. We develop the Moulin Shape (MouSh) model, a time-evolving model of moulin geometry. MouSh models ice deformation around a moulin using both viscous and elastic rheologies and melting within the moulin through heat dissipation from turbulent water flow, both above and below the water line. We force MouSh with idealized and realistic surface melt inputs. Our results show that variations in surface melt change the geometry of a moulin by approximately 10% daily and over 100% seasonally. These size variations cause observable differences in moulin water storage capacity and moulin water levels compared to a static, cylindrical moulin. Our results suggest that moulins are significant storage reservoirs for meltwater, with storage capacity and water levels varying over multiple timescales. Representing moulin geometry within subglacial hydrologic models may therefore improve the representation of subglacial pressures, especially over seasonal periods or in regions where overburden pressures are high. NASA Cryosphere 80NSSC19K0054
format Dataset
author Andrews, Lauren C.
Poinar, Kristin
Trunz, Celia
author_facet Andrews, Lauren C.
Poinar, Kristin
Trunz, Celia
author_sort Andrews, Lauren C.
title Data supporting "Controls on Greenland moulin geometry and evolution from the Moulin Shape model"
title_short Data supporting "Controls on Greenland moulin geometry and evolution from the Moulin Shape model"
title_full Data supporting "Controls on Greenland moulin geometry and evolution from the Moulin Shape model"
title_fullStr Data supporting "Controls on Greenland moulin geometry and evolution from the Moulin Shape model"
title_full_unstemmed Data supporting "Controls on Greenland moulin geometry and evolution from the Moulin Shape model"
title_sort data supporting "controls on greenland moulin geometry and evolution from the moulin shape model"
publishDate 2021
url http://hdl.handle.net/10477/82587
geographic Greenland
geographic_facet Greenland
genre Greenland
genre_facet Greenland
op_relation http://hdl.handle.net/10477/82587
_version_ 1766017437672669184

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