Investigating englacial reflections with vibro- and explosive-seismic surveys at Halvfarryggen ice dome, Antarctica

Explosive seismic reflection data from Halvfarryggen, a 910m thick local ice dome of the Antarctic ice sheet, show numerous laterally continuous reflections within the ice between 300 and 870m depth.We compare the quality of data obtained with explosive sources with that obtained using a vibroseis s...

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Bibliographic Details
Published in:Annals of Glaciology
Main Authors: Hofstede, Coen, Eisen, Olaf, Diez, Anja, Jansen, Daniela, Kristoffersen, Yngve, Lambrecht, Astrid, Mayer, Christoph
Format: Article in Journal/Newspaper
Language:unknown
Published: INT GLACIOL SOC 2013
Subjects:
Annals of Glaciology
Antarc*
Antarctic
Antarctica
Ice Sheet
Online Access:https://epic.awi.de/id/eprint/23921/
http://www.igsoc.org/annals/54/64/t64A064.html
https://hdl.handle.net/10013/epic.41852
Description
Summary:Explosive seismic reflection data from Halvfarryggen, a 910m thick local ice dome of the Antarctic ice sheet, show numerous laterally continuous reflections within the ice between 300 and 870m depth.We compare the quality of data obtained with explosive sources with that obtained using a vibroseis source for detecting englacial reflections with a snowstreamer, and investigate the origin of englacial reflections. We find vibroseis in combination with a snowstreamer is ten times more productive than explosive seismics. However, englacial reflections are more clearly visible with explosives, which have a broader bandwidth signature, than the vibroseis, which is band-limited at the high-frequency end to 100 Hz. Only the strongest and deepest englacial reflection is detected with vibroseis. We interpret the majority of englacial reflections to originate from changes in the crystal orientation fabric in closely spaced layers, less than the vibro-seismic tuning thickness of 13.5 m. Phase analysis of the lowermost englacial reflector, 40m above the bed, indicates a sharp increase in seismic wave speed. We interpret this reflector as a transition to a vertical single-maximum fabric. Our findings support current results from anisotropic ice-flow models, that crystal fabric is highly anisotropic at ice domes, both laterally and vertically.

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