The influence of environmental microseismicity on detection and interpretation of small-magnitude events in a polar glacier setting

Glacial environments exhibit temporally variable microseismicity. To investigate how microseismicity influences event detection, we implement two noise-adaptive digital power detectors to process seismic data from Taylor Glacier, Antarctica. We add scaled icequake waveforms to the original data stre...

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Bibliographic Details
Published in:Journal of Glaciology
Main Authors: Chris G. Carr, Joshua D. Carmichael, Erin C. Pettit, Martin Truffer
Format: Article in Journal/Newspaper
Language:English
Published: Cambridge University Press 2020
Subjects:
Antarctic glaciology
seismicity
seismology
Environmental sciences
GE1-350
Meteorology. Climatology
QC851-999
Antarctic
Taylor Glacier
Antarc*
Antarctica
Journal of Glaciology
Online Access:https://doi.org/10.1017/jog.2020.48
https://doaj.org/article/ad5dff689f51418995f1fc1012beec58
Description
Summary:Glacial environments exhibit temporally variable microseismicity. To investigate how microseismicity influences event detection, we implement two noise-adaptive digital power detectors to process seismic data from Taylor Glacier, Antarctica. We add scaled icequake waveforms to the original data stream, run detectors on the hybrid data stream to estimate reliable detection magnitudes and compare analytical magnitudes predicted from an ice crack source model. We find that detection capability is influenced by environmental microseismicity for seismic events with source size comparable to thermal penetration depths. When event counts and minimum detectable event sizes change in the same direction (i.e. increase in event counts and minimum detectable event size), we interpret measured seismicity changes as ‘true’ seismicity changes rather than as changes in detection. Generally, one detector (two degree of freedom (2dof)) outperforms the other: it identifies more events, a more prominent summertime diurnal signal and maintains a higher detection capability. We conclude that real physical processes are responsible for the summertime diurnal inter-detector difference. One detector (3dof) identifies this process as environmental microseismicity; the other detector (2dof) identifies it as elevated waveform activity. Our analysis provides an example for minimizing detection biases and estimating source sizes when interpreting temporal seismicity patterns to better infer glacial seismogenic processes.

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