Strain-Induced Fabric Development in Ice under Hydrostatic Pressure

Support is provided to allow the PIs to understand and model, through an improved understanding of grain boundary migration processes in deforming ice, the following phenomena: 1. The survival of extensive deformation and domination of the microstructure at depth of favorably-oriented grains, 2. The...

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Bibliographic Details
Main Author: Baker, Ian
Format: Dataset
Language:English
Published: Arctic Data Center 2015
Subjects:
ANS
Ice Sheet
Online Access:https://dx.doi.org/10.18739/a2zc7rt43
https://arcticdata.io/catalog/view/doi:10.18739/A2ZC7RT43
id ftdatacite:10.18739/a2zc7rt43
record_format openpolar
spelling ftdatacite:10.18739/a2zc7rt43 2023-05-15T16:41:24+02:00 Strain-Induced Fabric Development in Ice under Hydrostatic Pressure Baker, Ian 2015 text/xml https://dx.doi.org/10.18739/a2zc7rt43 https://arcticdata.io/catalog/view/doi:10.18739/A2ZC7RT43 en eng Arctic Data Center ANS dataset Dataset 2015 ftdatacite https://doi.org/10.18739/a2zc7rt43 2021-11-05T12:55:41Z Support is provided to allow the PIs to understand and model, through an improved understanding of grain boundary migration processes in deforming ice, the following phenomena: 1. The survival of extensive deformation and domination of the microstructure at depth of favorably-oriented grains, 2. The growth of slipping grains in the direction of shear, and whether this is a function of the relative orientations of neighboring grains or a fundamental characteristic of slipping grains, and 3. The effects of pressure on the rate and/or balance of the processes responsible for fabric development at depth. Their working hypothesis is that slipping grains can propagate without requiring recrystallization, and that this process is closely associated with anisotropy in grain boundary mobility during deformation. To seek evidence of these mechanisms, they propose the following series of laboratory observations on granular freshwater ice: 1. Conduct confined compression experiments at low deviatoric stresses and a range of pressure and temperature to develop a preferred c-axis orientation and cause growth. 2. Use standard techniques to document c-axis orientations, grain size and shape of the deformed microstructures for several temperatures and shear stress levels. 3. Employ electron backscatter pattern (EBSP) analysis to document a- and c-axis orientations of slipping and abutting grains in the deformed material. 4. Use surface etching to identify slip line arrays in the deforming grains, and couple these observations with the grain boundary structures observed in the EBSP results. The fundamental understanding derived from this study is anticipated to foster improved understanding of paleoclimate as derived from the interpretation of ice cores, as well as improved models of glacier and ice sheet mechanics. Dataset Ice Sheet DataCite Metadata Store (German National Library of Science and Technology)
institution Open Polar
collection DataCite Metadata Store (German National Library of Science and Technology)
op_collection_id ftdatacite
language English
topic ANS
spellingShingle ANS
Baker, Ian
Strain-Induced Fabric Development in Ice under Hydrostatic Pressure
topic_facet ANS
description Support is provided to allow the PIs to understand and model, through an improved understanding of grain boundary migration processes in deforming ice, the following phenomena: 1. The survival of extensive deformation and domination of the microstructure at depth of favorably-oriented grains, 2. The growth of slipping grains in the direction of shear, and whether this is a function of the relative orientations of neighboring grains or a fundamental characteristic of slipping grains, and 3. The effects of pressure on the rate and/or balance of the processes responsible for fabric development at depth. Their working hypothesis is that slipping grains can propagate without requiring recrystallization, and that this process is closely associated with anisotropy in grain boundary mobility during deformation. To seek evidence of these mechanisms, they propose the following series of laboratory observations on granular freshwater ice: 1. Conduct confined compression experiments at low deviatoric stresses and a range of pressure and temperature to develop a preferred c-axis orientation and cause growth. 2. Use standard techniques to document c-axis orientations, grain size and shape of the deformed microstructures for several temperatures and shear stress levels. 3. Employ electron backscatter pattern (EBSP) analysis to document a- and c-axis orientations of slipping and abutting grains in the deformed material. 4. Use surface etching to identify slip line arrays in the deforming grains, and couple these observations with the grain boundary structures observed in the EBSP results. The fundamental understanding derived from this study is anticipated to foster improved understanding of paleoclimate as derived from the interpretation of ice cores, as well as improved models of glacier and ice sheet mechanics.
format Dataset
author Baker, Ian
author_facet Baker, Ian
author_sort Baker, Ian
title Strain-Induced Fabric Development in Ice under Hydrostatic Pressure
title_short Strain-Induced Fabric Development in Ice under Hydrostatic Pressure
title_full Strain-Induced Fabric Development in Ice under Hydrostatic Pressure
title_fullStr Strain-Induced Fabric Development in Ice under Hydrostatic Pressure
title_full_unstemmed Strain-Induced Fabric Development in Ice under Hydrostatic Pressure
title_sort strain-induced fabric development in ice under hydrostatic pressure
publisher Arctic Data Center
publishDate 2015
url https://dx.doi.org/10.18739/a2zc7rt43
https://arcticdata.io/catalog/view/doi:10.18739/A2ZC7RT43
genre Ice Sheet
genre_facet Ice Sheet
op_doi https://doi.org/10.18739/a2zc7rt43
_version_ 1766031833550553088

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