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Effects of thermal variability on broadband seismometers; controlled experiments, observations, and implications

Claire D. Doody, Adam T. Ringler, R. E. Anthony, Dave C. Wilson, A. A. Holland, C. R. Hutt and L. D. Sandoval
Effects of thermal variability on broadband seismometers; controlled experiments, observations, and implications
Bulletin of the Seismological Society of America (February 2018) 108 (1): 493-502

Abstract

Isolating seismic instruments from temperature fluctuations is routine practice within the seismological community. However, the necessary degree of thermal stability required in broadband installations to avoid generating noise or compromising the fidelity in the seismic records is largely unknown and likely application dependent. To quantify the temperature sensitivity of seismometers over a broad range of frequencies, we artificially induced local temperature changes on three different models of seismometers to measure the effect of thermal variations on seismometer output. We found that diurnal temperature changes above 0.002 degrees C root mean square (rms) showed significant changes in velocity and acceleration output in comparison to thermally stable reference measurements. We also found that sensor incoherent self-noise increased with temperature variation; these increases in noise can be modeled as 1/f noise (pink noise), and are unlikely to be easily corrected for. These experimental results are compared with the data from Incorporated Research Institutions for Seismology (IRIS) U.S. Geological Survey (USGS) Global Seismographic Network (GSN) station TUC (Tucson, Arizona). This station is well instrumented with temperature sensors and has three different broadband seismometers, each of which uses a different method of thermal isolation. We show that the water bricks and borehole installations give ample temperature attenuation to thermally isolate seismometers from diurnal thermal variability that would compromise seismic data. We find that seismometer installations that provide thermal stability below 0.002 degrees C rms could help to improve long-period vertical seismic data across the GSN by decreasing temperature-driven 1/f noise.


ISSN: 0037-1106
EISSN: 1943-3573
Coden: BSSAAP
Serial Title: Bulletin of the Seismological Society of America
Serial Volume: 108
Serial Issue: 1
Title: Effects of thermal variability on broadband seismometers; controlled experiments, observations, and implications
Affiliation: University of Chicago, Department of Geophysical Sciences, Chicago, IL, United States
Pages: 493-502
Published: 201802
Text Language: English
Publisher: Seismological Society of America, Berkeley, CA, United States
References: 42
Accession Number: 2018-052128
Categories: Seismology
Document Type: Serial
Bibliographic Level: Analytic
Illustration Description: illus.
Secondary Affiliation: U. S. Geological Survey, USA, United StatesAlbuquerque Seismological Laboratory, USA, United States
Country of Publication: United States
Secondary Affiliation: GeoRef, Copyright 2018, American Geosciences Institute. Abstract, Copyright, Seismological Society of America. Reference includes data from GeoScienceWorld, Alexandria, VA, United States
Update Code: 2018
Program Name: USGSOPNon-USGS publications with USGS authors
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