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Glacier microseismicity

Geology
By: , and 
https://doi.org/10.1130/G30606.1

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Abstract

We present a framework for interpreting small glacier seismic events based on data collected near the center of Bering Glacier, Alaska, in spring 2007. We find extremely high microseismicity rates (as many as tens of events per minute) occurring largely within a few kilometers of the receivers. A high-frequency class of seismicity is distinguished by dominant frequencies of 20–35 Hz and impulsive arrivals. A low-frequency class has dominant frequencies of 6–15 Hz, emergent onsets, and longer, more monotonic codas. A bimodal distribution of 160,000 seismic events over two months demonstrates that the classes represent two distinct populations. This is further supported by the presence of hybrid waveforms that contain elements of both event types. The high-low-hybrid paradigm is well established in volcano seismology and is demonstrated by a comparison to earthquakes from Augustine Volcano. We build on these parallels to suggest that fluid-induced resonance is likely responsible for the low-frequency glacier events and that the hybrid glacier events may be caused by the rush of water into newly opening pathways.

Suggested Citation

West, M., Larsen, C., Truffer, M., O’Neel, S., and LeBlanc, L., 2010, Glacier microseismicity: Geology, v. 38, no. 4, p. 319-322, https://doi.org/10.1130/G30606.1.

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Publication type Article
Publication Subtype Journal Article
Title Glacier microseismicity
Series title Geology
DOI 10.1130/G30606.1
Volume 38
Issue 4
Year Published 2010
Language English
Contributing office(s) Alaska Science Center Water
Description 4 p.
Larger Work Type Article
Larger Work Subtype Journal Article
Larger Work Title Geology
First page 319
Last page 322
Country United States
State Alaska
Other Geospatial Bering Glacier
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