Active source seismology on the David Glacier marginal shear zone

We aim to use seismology to constrain the large scale crystallographic preferred orientation (CPO = crystal orientation fabric) across the David Glacier shear margin and satellite data to model the strain history that has resulted in the CPO. We will compare these data to results of thermo-mechanica...

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Bibliographic Details
Main Authors: David Prior, Huw Horgan, Won Sang Lee, Christina Hulbe, David Goldsby, Daeyeong Kim, Adam Treverrow
Format: Dataset
Language:unknown
Published: International Federation of Digital Seismograph Networks 2018
Subjects:
David Glacier
Online Access:https://dx.doi.org/10.7914/sn/8q_2018
https://www.fdsn.org/networks/detail/8Q_2018/
id ftdatacite:10.7914/sn/8q_2018
record_format openpolar
spelling ftdatacite:10.7914/sn/8q_2018 2023-05-15T16:00:08+02:00 Active source seismology on the David Glacier marginal shear zone David Prior Huw Horgan Won Sang Lee Christina Hulbe David Goldsby Daeyeong Kim Adam Treverrow 2018 SEED data https://dx.doi.org/10.7914/sn/8q_2018 https://www.fdsn.org/networks/detail/8Q_2018/ unknown International Federation of Digital Seismograph Networks Dataset dataset Seismic Network 2018 ftdatacite https://doi.org/10.7914/sn/8q_2018 2022-02-08T17:05:41Z We aim to use seismology to constrain the large scale crystallographic preferred orientation (CPO = crystal orientation fabric) across the David Glacier shear margin and satellite data to model the strain history that has resulted in the CPO. We will compare these data to results of thermo-mechanical forward models to establish whether strain dependent flow laws make a critical difference in controlling the shear margin mechanics and to define other measurements needed to test ice flow laws more completely. Receiver stations will be set up at three positions along a ~10km transect across the shear zone. Each receiver station will comprise a single three-component seismometer frozen into a 30-50m borehole and a surface array of 7 three-component geophones. One receiver station will have a line of 24 vertical component geophones that will be re-oriented for each shot. We have 14 seismic source sites, up to 10 km from the receiver stations. At each source site we will detonate three explosive shots (2.4kg Pentex: at ~ 20-30m depth). Source and receiver positions have been chosen to generate sufficient ray paths to distinguish likely CPOs using velocity anisotropy (P,S) and S-wave splitting. Local seismic refraction surveying will determine the seismic velocity structure. Dataset David Glacier DataCite Metadata Store (German National Library of Science and Technology) David Glacier ENVELOPE(160.000,160.000,-75.333,-75.333)
institution Open Polar
collection DataCite Metadata Store (German National Library of Science and Technology)
op_collection_id ftdatacite
language unknown
description We aim to use seismology to constrain the large scale crystallographic preferred orientation (CPO = crystal orientation fabric) across the David Glacier shear margin and satellite data to model the strain history that has resulted in the CPO. We will compare these data to results of thermo-mechanical forward models to establish whether strain dependent flow laws make a critical difference in controlling the shear margin mechanics and to define other measurements needed to test ice flow laws more completely. Receiver stations will be set up at three positions along a ~10km transect across the shear zone. Each receiver station will comprise a single three-component seismometer frozen into a 30-50m borehole and a surface array of 7 three-component geophones. One receiver station will have a line of 24 vertical component geophones that will be re-oriented for each shot. We have 14 seismic source sites, up to 10 km from the receiver stations. At each source site we will detonate three explosive shots (2.4kg Pentex: at ~ 20-30m depth). Source and receiver positions have been chosen to generate sufficient ray paths to distinguish likely CPOs using velocity anisotropy (P,S) and S-wave splitting. Local seismic refraction surveying will determine the seismic velocity structure.
format Dataset
author David Prior
Huw Horgan
Won Sang Lee
Christina Hulbe
David Goldsby
Daeyeong Kim
Adam Treverrow
spellingShingle David Prior
Huw Horgan
Won Sang Lee
Christina Hulbe
David Goldsby
Daeyeong Kim
Adam Treverrow
Active source seismology on the David Glacier marginal shear zone
author_facet David Prior
Huw Horgan
Won Sang Lee
Christina Hulbe
David Goldsby
Daeyeong Kim
Adam Treverrow
author_sort David Prior
title Active source seismology on the David Glacier marginal shear zone
title_short Active source seismology on the David Glacier marginal shear zone
title_full Active source seismology on the David Glacier marginal shear zone
title_fullStr Active source seismology on the David Glacier marginal shear zone
title_full_unstemmed Active source seismology on the David Glacier marginal shear zone
title_sort active source seismology on the david glacier marginal shear zone
publisher International Federation of Digital Seismograph Networks
publishDate 2018
url https://dx.doi.org/10.7914/sn/8q_2018
https://www.fdsn.org/networks/detail/8Q_2018/
long_lat ENVELOPE(160.000,160.000,-75.333,-75.333)
geographic David Glacier
geographic_facet David Glacier
genre David Glacier
genre_facet David Glacier
op_doi https://doi.org/10.7914/sn/8q_2018
_version_ 1766396011190681600

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