Ice microstructure (optical measurements) from Jarvis Glacier, Alaska, 2017-2020

Ice sheets and alpine glaciers discharge primarily though streaming flow, so the dynamics of that flow is central to the overall mass balance of the cryosphere. In glaciers and ice streams, the resistance to flow at the bed is important, but equally important is the internal viscous strength of the...

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Bibliographic Details
Main Authors: Christopher Gerbi, Renée Clavette
Format: Dataset
Language:unknown
Published: Arctic Data Center 2020
Subjects:
glaciers
microstructure
Jarvis Creek
Jarvis Glacier
glacier
ice core
Alaska
Online Access:https://doi.org/10.18739/A2BK16Q5T
id dataone:doi:10.18739/A2BK16Q5T
record_format openpolar
spelling dataone:doi:10.18739/A2BK16Q5T 2024-06-03T18:46:50+00:00 Ice microstructure (optical measurements) from Jarvis Glacier, Alaska, 2017-2020 Christopher Gerbi Renée Clavette Left margin of Jarvis (Creek) Glacier ENVELOPE(-145.68,-145.68,63.48,63.48) BEGINDATE: 2017-01-01T00:00:00Z ENDDATE: 2020-01-01T00:00:00Z 2020-01-01T00:00:00Z https://doi.org/10.18739/A2BK16Q5T unknown Arctic Data Center glaciers microstructure Dataset 2020 dataone:urn:node:ARCTIC https://doi.org/10.18739/A2BK16Q5T 2024-06-03T18:16:43Z Ice sheets and alpine glaciers discharge primarily though streaming flow, so the dynamics of that flow is central to the overall mass balance of the cryosphere. In glaciers and ice streams, the resistance to flow at the bed is important, but equally important is the internal viscous strength of the ice near the margins. In many cases, the lateral margins support greater than 50% of the resisting stress. At present, there is moderate to high uncertainty of the factors controlling the viscous strength of streaming ice under natural conditions. Although experiments suggest that variations in the intensity and orientation of the crystallographic fabric can result in up to a ten-fold difference in flow strength, in-situ observational studies of the microstructural architecture of streaming ice number in the low single digits. Most microstructural and in-situ rheological studies come from ice divides, near sites of paleoclimate coring. To complement that work and provide insight into the dynamic influence of streaming ice margins, our study documented both temperature and microstructure across a strain gradient at the lateral margin of Jarvis (Creek) Glacier and related those observations to modeled and observed 3D velocity structure. The dataset included here is one component of the larger project described above: crossed-polarized light images of thin-sections from three ice cores collected in spring 2017. Holes were drilled along a transect from less to more sheared ice, with the goal being to reach bed in at least two locations within the time constraints of the drilling season. We attempted six holes. Three were studied: JA, 63.4750˚N, 145.6753˚W, 1621 m elevation, 80 m long; JB, 63.4749˚N, 145.6759˚W, 1625 m, 30 m long; JE, 63.4743˚N, 145.6766˚W, 1625 m, 18 m long. JA and JE appear to have reached bed; other cores were limited by debris. We selected 12 samples from JA, 8 from JB, and 6 from JE to represent each ice core. For background, we also include a location map and core log. Dataset glacier glaciers ice core Alaska Arctic Data Center (via DataONE) Jarvis Creek ENVELOPE(-136.154,-136.154,63.700,63.700) Jarvis Glacier ENVELOPE(-136.537,-136.537,59.449,59.449) ENVELOPE(-145.68,-145.68,63.48,63.48)
institution Open Polar
collection Arctic Data Center (via DataONE)
op_collection_id dataone:urn:node:ARCTIC
language unknown
topic glaciers
microstructure
spellingShingle glaciers
microstructure
Christopher Gerbi
Renée Clavette
Ice microstructure (optical measurements) from Jarvis Glacier, Alaska, 2017-2020
topic_facet glaciers
microstructure
description Ice sheets and alpine glaciers discharge primarily though streaming flow, so the dynamics of that flow is central to the overall mass balance of the cryosphere. In glaciers and ice streams, the resistance to flow at the bed is important, but equally important is the internal viscous strength of the ice near the margins. In many cases, the lateral margins support greater than 50% of the resisting stress. At present, there is moderate to high uncertainty of the factors controlling the viscous strength of streaming ice under natural conditions. Although experiments suggest that variations in the intensity and orientation of the crystallographic fabric can result in up to a ten-fold difference in flow strength, in-situ observational studies of the microstructural architecture of streaming ice number in the low single digits. Most microstructural and in-situ rheological studies come from ice divides, near sites of paleoclimate coring. To complement that work and provide insight into the dynamic influence of streaming ice margins, our study documented both temperature and microstructure across a strain gradient at the lateral margin of Jarvis (Creek) Glacier and related those observations to modeled and observed 3D velocity structure. The dataset included here is one component of the larger project described above: crossed-polarized light images of thin-sections from three ice cores collected in spring 2017. Holes were drilled along a transect from less to more sheared ice, with the goal being to reach bed in at least two locations within the time constraints of the drilling season. We attempted six holes. Three were studied: JA, 63.4750˚N, 145.6753˚W, 1621 m elevation, 80 m long; JB, 63.4749˚N, 145.6759˚W, 1625 m, 30 m long; JE, 63.4743˚N, 145.6766˚W, 1625 m, 18 m long. JA and JE appear to have reached bed; other cores were limited by debris. We selected 12 samples from JA, 8 from JB, and 6 from JE to represent each ice core. For background, we also include a location map and core log.
format Dataset
author Christopher Gerbi
Renée Clavette
author_facet Christopher Gerbi
Renée Clavette
author_sort Christopher Gerbi
title Ice microstructure (optical measurements) from Jarvis Glacier, Alaska, 2017-2020
title_short Ice microstructure (optical measurements) from Jarvis Glacier, Alaska, 2017-2020
title_full Ice microstructure (optical measurements) from Jarvis Glacier, Alaska, 2017-2020
title_fullStr Ice microstructure (optical measurements) from Jarvis Glacier, Alaska, 2017-2020
title_full_unstemmed Ice microstructure (optical measurements) from Jarvis Glacier, Alaska, 2017-2020
title_sort ice microstructure (optical measurements) from jarvis glacier, alaska, 2017-2020
publisher Arctic Data Center
publishDate 2020
url https://doi.org/10.18739/A2BK16Q5T
op_coverage Left margin of Jarvis (Creek) Glacier
ENVELOPE(-145.68,-145.68,63.48,63.48)
BEGINDATE: 2017-01-01T00:00:00Z ENDDATE: 2020-01-01T00:00:00Z
long_lat ENVELOPE(-136.154,-136.154,63.700,63.700)
ENVELOPE(-136.537,-136.537,59.449,59.449)
ENVELOPE(-145.68,-145.68,63.48,63.48)
geographic Jarvis Creek
Jarvis Glacier
geographic_facet Jarvis Creek
Jarvis Glacier
genre glacier
glaciers
ice core
Alaska
genre_facet glacier
glaciers
ice core
Alaska
op_doi https://doi.org/10.18739/A2BK16Q5T
_version_ 1800871933601906688

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