Response of hydrothermal system to stress transients at Lassen Volcanic Center, California, inferred from seismic interferometry with ambient noise

Taira, T.; Brenguier, Florent

doi:10.1186/s40623-016-0538-6

Cited by 32 publications

(27 citation statements)

References 64 publications

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“…We attribute decreases in seismic velocities to increases in crack opening induced by stress transients. Under this assumption, the sensitivity of velocity changes to external stress transients (η) was evaluated through the ratio of relative seismic velocity change (Δ v = dv / v ) and external stress transient (Δσ), η = (Δ v /Δσ) ( 15 , 35 , 36 ). If crack density (ρ c ) governs the velocity reduction, this stress sensitivity can be decomposed into two terms expressed as η = (Δ v /Δρ c )(Δρ c /Δσ) ( 37 ).…”

Section: Discussionmentioning

confidence: 99%

Monitoring reservoir response to earthquakes and fluid extraction, Salton Sea geothermal field, California

et al. 2018

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Section: Discussionmentioning

confidence: 99%

Monitoring reservoir response to earthquakes and fluid extraction, Salton Sea geothermal field, California

et al. 2018

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“…Particular attention has been paid to understand the effect that the inhomogeneous distribution of noise sources would have on the coherence or cross‐correlation measured between stations, with the goal of determining whether measurements can be reliably used for the study of seismic velocities or attenuation (e.g., Cupillard & Capdeville, ; Harmon et al, ; Lawrence & Prieto, ; Tsai, , ; Weaver, ; Yang & Ritzwoller, ), with additional studies exploring the extent to which signal preprocessing can reduce the effect of inhomogeneous noise sources (e.g., Bensen et al, ; Viens et al, ). Some of these velocity or attenuation measurements require a great amount of precision and stability over time (Froment et al, ), such as for the observation of material velocity changes; velocity variations on a daily or monthly time scale may be as small as a couple percent but have been shown to yield valuable information regarding temperature or pore pressure changes (i.e., Brenguier et al, ; Lecocq et al, ; Taira & Brenguier, ). This paper explores two aspects of such cross‐correlation or coherence‐based observations that affect the final precision with which measurements may be reliably made.…”

Section: Introductionmentioning

confidence: 99%

Coherence‐Based Approaches for Estimating the Composition of the Seismic Wavefield

et al. 2019

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As new techniques exploiting the Earth's ambient seismic noise field are developed and applied, such as for the observation of temporal changes in seismic velocity structure, it is crucial to quantify the precision with which wave‐type measurements can be made. This work uses array data at the Homestake mine in Lead, South Dakota, and an array at Sweetwater, Texas, to consider two aspects that control this precision: the types of seismic wave contributing to the ambient noise field at microseism frequencies and the effect of array geometry. Both are quantified using measurements of wavefield coherence between stations in combination with Wiener filters. We find a strong seasonal change between body‐wave and surface‐wave content. Regarding the inclusion of underground stations, we quantify the lower limit to which the ambient noise field can be characterized and reproduced; the applications of the Wiener filters are about 4 times more successful in reproducing ambient noise waveforms when underground stations are included in the array, resulting in predictions of seismic time series with less than a 1% residual, and are ultimately limited by the geometry and aperture of the array, as well as by temporal variations in the seismic field. We discuss the implications of these results for the geophysics community performing ambient seismic noise studies, as well as for the cancellation of seismic Newtonian gravity noise in ground‐based, sub‐Hertz, gravitational‐wave detectors.

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“…The continuous monitoring of seismic velocities offers a new tool to capture the physical processes that take place after large earthquakes. This can provide insights not only into the tectonic and volcanic processes (Brenguier, Campillo, et al, ; Brenguier, Shapiro, et al, ; Brenguier et al, ; Chen et al, ; Froment et al, ; Obermann et al, ; Taira & Brenguier, ; Wegler et al, ) but also into some transient fluctuations that are derived from external environmental perturbations (Sens‐Schönfelder & Wegler, ; Meier et al, ; Hillers et al, ; Hillers, Ben‐Zion, et al, ; Wang et al, ). The characteristic depth at which such changes can be monitored varies from meters (Hillers, Retailleau, et al, ; Mao et al, ; Sens‐Schönfelder & Wegler, ) down to dozens of kilometers into the crust (Froment et al, ; Obermann et al, ; Rivet et al, ), through measurements at various periods.…”

Section: Introductionmentioning

confidence: 99%

Evidence of Changes of Seismic Properties in the Entire Crust Beneath Japan After the M_w 9.0, 2011 Tohoku‐oki Earthquake

et al. 2019

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Studies of mechanical responses of the Earth crust to large earthquakes can provide us with unique insights into the processes of stress buildup and release. As a complement to geodetic methods that derive crustal strain dynamics from surface observations (e.g., GPS, InSAR), noise‐based seismic velocity monitoring directly probes the mechanical state of the crust, at depth and continuously in time. We investigate the responses of the crust to the Mw 9.0, 2011 Tohoku‐oki earthquake. In addition to the Hi‐net short‐period sensors, we use Hi‐net tiltmeters as long‐period seismometers (8–50 s) to sample the crust below 5 km in depth. The spatial distribution of the strong velocity decreases at short periods appears to be limited to the region of strong ground shaking induced by the 2011 Tohoku‐oki earthquake, while the long‐period velocity changes correlate well with the modeled static strain induced by viscoelastic relaxation and afterslip at depth. Amplitudes of coseismic velocity changes decrease with increasing depth. The temporal evolution of velocity changes in different period bands shows that the maximum drops in the velocity at long periods are delayed in time with respect to the occurrence of the Tohoku‐oki earthquake. The inversion of seismic velocity changes at depth illustrates how S wave velocities evolve down to 40 km at a regional scale after a major earthquake.

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Response of hydrothermal system to stress transients at Lassen Volcanic Center, California, inferred from seismic interferometry with ambient noise

Cited by 32 publications

References 64 publications

Monitoring reservoir response to earthquakes and fluid extraction, Salton Sea geothermal field, California

Monitoring reservoir response to earthquakes and fluid extraction, Salton Sea geothermal field, California

Coherence‐Based Approaches for Estimating the Composition of the Seismic Wavefield

Evidence of Changes of Seismic Properties in the Entire Crust Beneath Japan After the M_w 9.0, 2011 Tohoku‐oki Earthquake

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Response of hydrothermal system to stress transients at Lassen Volcanic Center, California, inferred from seismic interferometry with ambient noise

Cited by 32 publications

References 64 publications

Monitoring reservoir response to earthquakes and fluid extraction, Salton Sea geothermal field, California

Monitoring reservoir response to earthquakes and fluid extraction, Salton Sea geothermal field, California

Coherence‐Based Approaches for Estimating the Composition of the Seismic Wavefield

Evidence of Changes of Seismic Properties in the Entire Crust Beneath Japan After the Mw 9.0, 2011 Tohoku‐oki Earthquake

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Product

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Evidence of Changes of Seismic Properties in the Entire Crust Beneath Japan After the M_w 9.0, 2011 Tohoku‐oki Earthquake