Distributed Acoustic Sensing in Volcano‐Glacial Environments—Mount Meager, British Columbia

We demonstrate the logistic feasibility and scientific potential of distributed acoustic sensing (DAS) in alpine volcano‐glacial environments that are subject to a broad range of natural hazards. Our work considers the Mount Meager massif, an active volcanic complex in British Columbia, estimated to...

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Bibliographic Details
Published in:Journal of geophysical research. Solid earth 2021-11, Vol.126 (11), p.n/a
Main Authors: Klaasen, Sara, Paitz, Patrick, Lindner, Nadja, Dettmer, Jan, Fichtner, Andreas
Format: Article
Language:English
Subjects:
Acoustic imagery
Acoustic microscopy
Acoustics
Algorithms
Beamforming
Cables
Data acquisition
Data analysis
Directional sensitivity
distributed acoustic sensing
Earthquakes
Feasibility studies
Fluids
Geophysics
geothermal energy
Geothermal resources
Glaciers
glaciology
Ground motion
Hazardous areas
Landslides
Lasers
Logistics
Long fibers
Massifs
Mount Meager
New technology
P-waves
Reservoirs
Seismic activity
Seismic propagation
Seismic wave propagation
Seismic waves
Seismicity
Seismographs
Seismometers
Tremors
volcano seismology
Volcanoes
Wave propagation
Waveforms
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Summary:We demonstrate the logistic feasibility and scientific potential of distributed acoustic sensing (DAS) in alpine volcano‐glacial environments that are subject to a broad range of natural hazards. Our work considers the Mount Meager massif, an active volcanic complex in British Columbia, estimated to have the largest geothermal potential in Canada, and home of Canada's largest recorded landslide in 2010. From September to October 2019, we acquired continuous strain data, using a 3‐km long fiber‐optic cable, deployed on a ridge of Mount Meager and on the uppermost part of a glacier above 2,000 m altitude. The data analysis detected a broad range of unexpectedly intense, low‐magnitude, local seismicity. The most prominent events include long‐lasting, intermediate‐frequency (0.01–1 Hz) tremor, and high‐frequency (5–45 Hz) earthquakes that form distinct spatial clusters and often repeat with nearly identical waveforms. We conservatively estimate that the number of detectable high‐frequency events varied between several tens and nearly 400 per day. We also develop a beamforming algorithm that uses the signal‐to‐noise ratio (SNR) of individual channels, and implicitly takes the direction‐dependent sensitivity of DAS into account. Both the tremor and the high‐frequency earthquakes are most likely related to fluid movement within Mount Meager's geothermal reservoir. Our work illustrates that DAS carries the potential to reveal previously undiscovered seismicity in challenging environments, where comparably dense arrays of conventional seismometers are difficult to install. We hope that the logistics and deployment details provided here may serve as a starting point for future DAS experiments. Plain Language Summary Distributed acoustic sensing (DAS) is an emerging technology to measure microscopic ground motion by sending laser pulses through fiber‐optic cables, which are commonly used for telecommunication. A cable of several kilometers length provides thousands of measurement points, which can yield highly detailed information about the propagation of seismic waves excited by earthquakes. The ease of deploying a fiber‐optic cable, compared to the challenge of installing thousands of conventional seismometers, opens new opportunities for earthquake studies in remote and hazardous areas. Here, we present the first application of DAS in a volcano‐glacial environment. Mount Meager, the site of the experiment in British Columbia, is an active volcano known for its geo
ISSN:2169-9313
2169-9356
DOI:10.1029/2021JB022358