Flow in naturally deformed ice: a cryogenic EBSD and modelling study of the NEEM ice core
Understanding the flow of ice is essential to predict the contribution of the polar ice sheets to global mean sea level rise in the next decades and centuries. During this PhD project, the recrystallization and deformation mechanisms that govern the flow of ice were studied along the length of the N...
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Utrecht Studies in Earth Sciences
2019
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| Online Access: | https://epic.awi.de/id/eprint/49288/ https://dspace.library.uu.nl/handle/1874/374618 https://hdl.handle.net/10013/epic.97c9124d-adb9-4c9b-938b-64e1ccbebe6b |
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ftawi:oai:epic.awi.de:49288 2024-09-15T18:09:39+00:00 Flow in naturally deformed ice: a cryogenic EBSD and modelling study of the NEEM ice core Kuiper, Ernst-Jan 2019-02-01 https://epic.awi.de/id/eprint/49288/ https://dspace.library.uu.nl/handle/1874/374618 https://hdl.handle.net/10013/epic.97c9124d-adb9-4c9b-938b-64e1ccbebe6b unknown Utrecht Studies in Earth Sciences Kuiper, E. J. (2019) Flow in naturally deformed ice: a cryogenic EBSD and modelling study of the NEEM ice core , PhD thesis, Utrecht University, Dept. of Earth Sciences. hdl:10013/epic.97c9124d-adb9-4c9b-938b-64e1ccbebe6b EPIC3Utrecht Studies in Earth Sciences, 250 p. Thesis notRev 2019 ftawi 2024-06-24T04:22:11Z Understanding the flow of ice is essential to predict the contribution of the polar ice sheets to global mean sea level rise in the next decades and centuries. During this PhD project, the recrystallization and deformation mechanisms that govern the flow of ice were studied along the length of the North Greenland Eemian Ice Drilling (NEEM) ice core in northwest Greenland. Two methods were used during this study: (i) cryogenic electron backscatter diffraction (cryo-EBSD) in combination with (polarized) light microscopy and (ii) flow law modelling using two different flow laws for ice constrained by the actual temperature and grain size data from the NEEM ice core. The NEEM ice core was divided up into three depth intervals originating from different climatic stages that differ strongly in terms of impurity content, microstructure, deformation mode and temperature: the Holocene ice (01419 m of depth), the glacial ice (1419-2207 m of depth) and the Eemian-glacial facies (2207-2540 m of depth). Microstructures indicate that the Holocene ice deforms by the easy slip system (crystallographic basal slip) accommodated by the harder slip systems (non-basal slip), also known as dislocation creep, and by recovery via strain induced boundary migration (SIBM), which removes dislocations and stress concentrations and allows further deformation to occur. The amount of non-basal slip that is activated is controlled by the extent of SIBM. The dominant recrystallization mechanisms in the Holocene ice are SIBM, bulging recrystallization and grain dissection in total leading to dynamic grain growth, with a contribution from normal grain growth in the upper 250 m. The strain rate variability with depth in the Holocene ice, estimated by flow law modelling, is low. In contrast, the strain rate variability is relatively high in the glacial ice as a result of variability in grain boundary sliding (GBS) with depth that accommodates basal slip (GBS-limited creep). Grain boundary sliding in the glacial ice is particularly strong in fine ... Thesis Greenland ice core North Greenland Alfred Wegener Institute for Polar- and Marine Research (AWI): ePIC (electronic Publication Information Center) |
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Alfred Wegener Institute for Polar- and Marine Research (AWI): ePIC (electronic Publication Information Center) |
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ftawi |
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Understanding the flow of ice is essential to predict the contribution of the polar ice sheets to global mean sea level rise in the next decades and centuries. During this PhD project, the recrystallization and deformation mechanisms that govern the flow of ice were studied along the length of the North Greenland Eemian Ice Drilling (NEEM) ice core in northwest Greenland. Two methods were used during this study: (i) cryogenic electron backscatter diffraction (cryo-EBSD) in combination with (polarized) light microscopy and (ii) flow law modelling using two different flow laws for ice constrained by the actual temperature and grain size data from the NEEM ice core. The NEEM ice core was divided up into three depth intervals originating from different climatic stages that differ strongly in terms of impurity content, microstructure, deformation mode and temperature: the Holocene ice (01419 m of depth), the glacial ice (1419-2207 m of depth) and the Eemian-glacial facies (2207-2540 m of depth). Microstructures indicate that the Holocene ice deforms by the easy slip system (crystallographic basal slip) accommodated by the harder slip systems (non-basal slip), also known as dislocation creep, and by recovery via strain induced boundary migration (SIBM), which removes dislocations and stress concentrations and allows further deformation to occur. The amount of non-basal slip that is activated is controlled by the extent of SIBM. The dominant recrystallization mechanisms in the Holocene ice are SIBM, bulging recrystallization and grain dissection in total leading to dynamic grain growth, with a contribution from normal grain growth in the upper 250 m. The strain rate variability with depth in the Holocene ice, estimated by flow law modelling, is low. In contrast, the strain rate variability is relatively high in the glacial ice as a result of variability in grain boundary sliding (GBS) with depth that accommodates basal slip (GBS-limited creep). Grain boundary sliding in the glacial ice is particularly strong in fine ... |
| format |
Thesis |
| author |
Kuiper, Ernst-Jan |
| spellingShingle |
Kuiper, Ernst-Jan Flow in naturally deformed ice: a cryogenic EBSD and modelling study of the NEEM ice core |
| author_facet |
Kuiper, Ernst-Jan |
| author_sort |
Kuiper, Ernst-Jan |
| title |
Flow in naturally deformed ice: a cryogenic EBSD and modelling study of the NEEM ice core |
| title_short |
Flow in naturally deformed ice: a cryogenic EBSD and modelling study of the NEEM ice core |
| title_full |
Flow in naturally deformed ice: a cryogenic EBSD and modelling study of the NEEM ice core |
| title_fullStr |
Flow in naturally deformed ice: a cryogenic EBSD and modelling study of the NEEM ice core |
| title_full_unstemmed |
Flow in naturally deformed ice: a cryogenic EBSD and modelling study of the NEEM ice core |
| title_sort |
flow in naturally deformed ice: a cryogenic ebsd and modelling study of the neem ice core |
| publisher |
Utrecht Studies in Earth Sciences |
| publishDate |
2019 |
| url |
https://epic.awi.de/id/eprint/49288/ https://dspace.library.uu.nl/handle/1874/374618 https://hdl.handle.net/10013/epic.97c9124d-adb9-4c9b-938b-64e1ccbebe6b |
| genre |
Greenland ice core North Greenland |
| genre_facet |
Greenland ice core North Greenland |
| op_source |
EPIC3Utrecht Studies in Earth Sciences, 250 p. |
| op_relation |
Kuiper, E. J. (2019) Flow in naturally deformed ice: a cryogenic EBSD and modelling study of the NEEM ice core , PhD thesis, Utrecht University, Dept. of Earth Sciences. hdl:10013/epic.97c9124d-adb9-4c9b-938b-64e1ccbebe6b |
| _version_ |
1810447234655846400 |