Seasonal Crustal Seismic Velocity Changes Throughout Japan

Wang, Qing‐Yu; Brenguier, Florent; Campillo, Míchel; Lecointre, Albanne; Takeda, Tetsuya; Aoki, Yosuke

doi:10.1002/2017jb014307

Cited by 120 publications

(221 citation statements)

References 44 publications

(76 reference statements)

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“…Recent studies have tried to apply corrections for changes induced by rainfall (e.g., Budi-Santoso & Lesage, 2016;Lecocq et al, 2017;Rivet et al, 2015;Wang et al, 2017) and thermoelastic strain (e.g., Lecocq et al, 2017). Recent studies have tried to apply corrections for changes induced by rainfall (e.g., Budi-Santoso & Lesage, 2016;Lecocq et al, 2017;Rivet et al, 2015;Wang et al, 2017) and thermoelastic strain (e.g., Lecocq et al, 2017).…”

Section: Volcanic Versus Nonvolcanic Sourcesmentioning

confidence: 99%

Volcanic, Coseismic, and Seasonal Changes Detected at White Island (Whakaari) Volcano, New Zealand, Using Seismic Ambient Noise

Yates

Savage

Jolly

et al. 2019

Geophysical Research Letters

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Ambient noise interferometry is becoming increasingly popular for studying seismic velocity changes. Such changes contain information on the structural and mechanical properties of Earth systems. Application to monitoring, however, is complicated by the large number of processes capable of inducing crustal velocity changes. We demonstrate this at White Island volcano over a 10‐year period containing multiple well‐documented eruptions. Using individual seismic stations, we detect velocity perturbations that we ascribe to volcanic activity, large earthquakes, and seasonality. Distant seismic stations capture widespread nonvolcanic changes that are also present at the volcano. Comparison between velocity changes recorded by distant and local stations then allows us to distinguish volcanic phenomena from seasonality. Through this, we resolve distinct features in ambient noise‐derived velocity changes that relate to volcanic unrest and a phreatic eruption, illustrating the strength of the approach.

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Section: Volcanic Versus Nonvolcanic Sourcesmentioning

confidence: 99%

Volcanic, Coseismic, and Seasonal Changes Detected at White Island (Whakaari) Volcano, New Zealand, Using Seismic Ambient Noise

Yates

Savage

Jolly

et al. 2019

Geophysical Research Letters

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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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“…Such seismic velocity reductions are expected to be shallow and to correlate with the strength of shaking, which is clarified by analyzing seismic data recorded at the top and bottom of a borehole (Nakata & Snieder, ; Sawazaki et al, ; Takagi et al, ). Water level variation due to precipitation leads to pore pressure changes, and seismic velocity changes thereby are also sensitive to precipitation (Meier et al, ; Rivet et al, ; Sens‐Schönfelder & Wegler, ; Wang et al, ). Strain changes cause preexisting cracks to close and open, and consequently the seismic velocities decrease and increase in regions of dilatation and contraction of the structure, respectively (e.g., Nur, ; Walsh, ).…”

Section: Introductionmentioning

confidence: 99%

Sensitivity of Seismic Velocity Changes to the Tidal Strain at Different Lapse Times: Data Analyses of a Small Seismic Array at Izu‐Oshima Volcano

et al. 2019

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We investigate seismic velocity changes in response to the tidal strain at Izu‐Oshima volcano, Japan, by analyzing the data of permanent seismic stations and a small seismic array to evaluate the characteristics of strain sensitivity of velocity changes. We estimate the seismic velocity changes by phase differences between cross‐correlations functions of ambient noises at the frequency of 2–4 Hz stacked for time periods with different tidal strain amplitudes. The seismic velocity changes decrease and increase during dilatation and contraction periods, respectively, when analyzing the cross‐correlations functions at early lapse times ranging from 2 to 7 s. The strain sensitivity of seismic velocity changes is estimated to be ()−2.1±0.2×104 at the early lapse times. However, we find that strain sensitivity of the seismic velocity changes decreases when analyzing the cross‐correlation functions at later lapse times from 7 s to 35 s. Applying an array analysis to the cross‐correlation functions, we observe apparent velocities of about 1 km/s at the early lapse times and those of higher than 1 km/s at the late lapse times. Since the group velocity of Rayleigh waves is 1.1 km/s at Izu‐Oshima volcano, the apparent velocities at the late lapse times may indicate the scattered or reflected body waves incident from a deeper region. Decrease of strain sensitivity with the lapse times therefore results from the emergence of body waves on the late lapse times. These results highlight the need to pay attention to wave types of cross‐correlation functions and their paths to interpret seismic velocity changes.

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Seasonal Crustal Seismic Velocity Changes Throughout Japan

Cited by 120 publications

References 44 publications

Volcanic, Coseismic, and Seasonal Changes Detected at White Island (Whakaari) Volcano, New Zealand, Using Seismic Ambient Noise

Volcanic, Coseismic, and Seasonal Changes Detected at White Island (Whakaari) Volcano, New Zealand, Using Seismic Ambient Noise

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

Sensitivity of Seismic Velocity Changes to the Tidal Strain at Different Lapse Times: Data Analyses of a Small Seismic Array at Izu‐Oshima Volcano

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Seasonal Crustal Seismic Velocity Changes Throughout Japan

Cited by 120 publications

References 44 publications

Volcanic, Coseismic, and Seasonal Changes Detected at White Island (Whakaari) Volcano, New Zealand, Using Seismic Ambient Noise

Volcanic, Coseismic, and Seasonal Changes Detected at White Island (Whakaari) Volcano, New Zealand, Using Seismic Ambient Noise

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

Sensitivity of Seismic Velocity Changes to the Tidal Strain at Different Lapse Times: Data Analyses of a Small Seismic Array at Izu‐Oshima Volcano

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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