High resolutionQ−1estimation based on extension of coda normalization method and its application toP-wave attenuation structure in the aftershock area of the 2005 West Off Fukuoka Prefecture Earthquake (M7.0)

Matsumoto, Satoshi; Uehira, Kenji; Watanabe, Atsushi; Goto, Kazuhiko; Iio, Yoshihisa; Hirata, Naoshi; Okada, Tomomi; Takahashi, Hiroaki; Shimizu, Hiroshi; Shinohara, Masanao; Kanazawa, Toshihiko

doi:10.1111/j.1365-246x.2009.04313.x

Cited by 15 publications

(12 citation statements)

References 33 publications

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“…The spatial distribution of Q in the crust has been drawing attention from seismologists, and a number of studies employing local earthquake tomography techniques to obtain the 3-D distribution of Q have been conducted. 3-D Q tomography is an effective tool for inferring the underground distribution of fracture density and the roles of fluids in the crust (e.g., Rietbrock 2001;Reyners et al 2007;Bennington et al 2008). Matsumoto et al (2009 reported that a high Q P region corresponds to a large-slip fault patch where a large inland shallow earthquake occurred (the 2005 West off-Fukuoka earthquake, Mw 7.0), suggesting a correlation between the frictional strength along the fault and the seismic attenuation of the host rocks.…”

Section: Discussionmentioning

confidence: 99%

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QP structure of the accretionary wedge in the Kumano Basin, Nankai Trough, Japan, revealed by long-offset walk-away VSP

Hino

Tsuji

Bangs

et al. 2015

Earth, Planets and Space

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We determined the seismic attenuation structure of the Kumano Basin, a forearc basin in the central part of the Nankai subduction zone. Despite its importance for understanding the physical condition of the Earth's interior and seismic wave propagation processes, the attenuation factor Q has been poorly estimated in the crustal layers of the offshore areas of Nankai because severe attenuation occurring in the seafloor sediments prevents the reliable estimation of Q from conventional active source seismic surveys. In the present study, we derive Q values from the diminishing rate of the high-frequency contents of seismic energy during propagation through sub-seafloor layers. The records of vertical seismic profiling acquired at approximately 1,000 m below the seafloor, which have fewer effects from shallow attenuation, enabled us to elucidate depth variation of Q of P waves (Q P), the attenuation factor of P waves, down to approximately 8 km below the seafloor. Assuming that the frequency dependence of Q is small and using a previously obtained P-wave velocity structure model for the basin, we inverted the fall-off rate of the spectral ratios at various shot-receiver distances to obtain Q P in the three sub-bottom layers. The Q P values for the upper two layers with P-wave velocity (V P) < 2.7 km/s are 34 and 57. These values are almost identical to those obtained in the North Atlantic, suggesting the broad consistency of Q P within seafloor sediment. The basement layer (V P approximately 4 km/s) has a much higher Q P value of 349, which is comparable to the value estimated for crustal layers exposed onshore. This Q P value is higher than the value previously assumed in a simulation of strong ground motion associated with megathrust earthquakes along the Nankai margin. We interpret that the high Q P , low seismic attenuation in the basement layer reflects tectonic stability of the inner wedge of the accretionary margin. Our first estimates of Q P in the present study provide a strong basis for future studies of seismic structure and strong ground motion prediction.

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Section: Discussionmentioning

confidence: 99%

“…In the inversion, we applied a nonnegative least squares method (Lawson and Hanson 1995) because Q −1 P,i cannot take negative values. Note that the first and second integrals (summations) of the observation Equation 5 are evaluated along the ray path from the source at x and along that from the source at x 0 , respectively.…”

Section: Introductionmentioning

confidence: 99%

QP structure of the accretionary wedge in the Kumano Basin, Nankai Trough, Japan, revealed by long-offset walk-away VSP

Hino

Tsuji

Bangs

et al. 2015

Earth, Planets and Space

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“…In these media, we may retrieve P-and S-wave attenuation parameters independently of the site and instrumental transfer functions by using the coda normalization method (Aki and Richards 1980;Yoshimoto et al 1993;Sato et al 2012). In recent years, this method has been applied to S-wave attenuation tomography at local scale, exploiting the strong scattering effects produced by strong heterogeneity in volcanic regions (Del Pezzo et al 2006;Matsumoto et al 2009;Sato et al 2012;De Siena et al 2010). The coda normalization method is based on the equation that correlates the ratio between the S-wave direct energy and the coda wave energy to the spatial distribution of the inverse total quality factors calculated along the source-station ray-path (Del Pezzo et al 2006;De Siena et al 2009.…”

Section: Introductionmentioning

confidence: 99%

The 3D Attenuation Structure of Deception Island (Antarctica)

et al. 2015

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The seismic and volcanological structure of Deception Island (Antarctica) is an intense focus topic in Volcano Geophysics. The interpretations given by scientists on the origin, nature, and location of the structures buried under the island strongly diverge. We present a high-resolution 3D P-wave attenuation tomography model obtained by using the coda normalization method on 20,293 high-quality waveforms produced by active sources. The checkerboard and synthetic anomaly tests guarantee the reproduction of the input anomalies under the island down to a depth of 4 km. The results, once compared with our current knowledge on the geological, geochemical, and geophysical structure of the region, depict Deception as a piecemeal caldera structure coming out of the Bransfield Trough. Highattenuation anomalies contouring the northeastern emerged caldera rim correlate with the locations of sediments. In our interpretation, the main attenuation contrast, which appears under the collapsed southeastern caldera rim, is related to the deeper feeding systems. A unique P-wave high-attenuation spherical-like anomaly in the inner bay extends between depths of 1 and 3 km. The northern contour of the anomaly coincides with the calderic rim both at 1 and 2 km, while smaller anomalies connect it with deeper structures below 3 km, dipping toward the Bransfield Trough. In our interpretation, the large upper anomaly is caused by a high-temperature shallow (1-3 km deep) geothermal system, located beneath the sediment-filled bay in the collapsed blocks and heated by smaller, deeper contributions of molten materials (magma) rising from southeast.

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“…Seismic velocity tomography has proven to be a powerful technique to investigate the 3-D crustal and upper mantle structure and seismotectonics [e.g., Zhao et al, 1996;Mishra and Zhao, 2003;Kato et al, 2005;Wang and Zhao, 2006;Wang et al, 2016]. Compared to velocity tomography, seismic attenuation tomography has rarely been applied to large earthquake areas [e.g., Rietbrock, 2001;Matsumoto et al, 2009]. Because seismic attenuation is more sensitive than seismic velocity to some important material properties, such as Journal of Geophysical Research: Solid Earth 10.1002/2016JB013704 temperature, grain size, and water content Toksöz et al, 1979;Jackson et al, 2002;Faul and Jackson, 2005;Aizawa et al, 2008], seismic attenuation tomography is suitable for investigating very heterogeneous regions such as subduction zones [e.g., Eberhart-Phillips and Chadwick, 2002;Schurr et al, 2003;Stachnik et al, 2004;Pozgay et al, 2009;Bohm et al, 2013;Nakajima et al, 2013;Liu et al, 2014;Liu and Zhao, 2015;Saita et al, 2015].…”

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confidence: 99%

Seismic attenuation tomography of the source zone of the 2016 Kumamoto earthquake (M 7.3)

et al. 2017

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We study the three‐dimensional seismic attenuation (QP and QS) structure in the source area of the 2016 Kumamoto earthquake (M 7.3) by using 18,296 tP* and 29,668 tS* data from 742 local earthquakes recorded by a dense seismic network consisting of 112 stations deployed in Kyushu Island. Our results show that significant low‐Q (high‐attenuation) anomalies exist in the crust and mantle wedge beneath the volcanic front and back‐arc area, which reflect hot and wet zones caused by convective circulation in the mantle wedge and dehydration of the young Philippine Sea (PHS) slab. The 2016 Kumamoto earthquake occurred in a high‐Q and high‐velocity (high‐V) zone in the upper crust, which is surrounded and underlain by low‐Q and low‐V anomalies in the lower crust and upper mantle. These results suggest that the 2016 Kumamoto earthquake took place in a brittle seismogenic layer in the upper crust, but its rupture nucleation was affected by fluids and arc magma ascending from the mantle wedge. In addition, an obvious low‐Q zone is revealed in the fore‐arc mantle wedge, which reflects serpentinization of the fore‐arc mantle due to abundant fluids from the PHS slab dehydration.

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High resolutionQ⁻¹estimation based on extension of coda normalization method and its application toP-wave attenuation structure in the aftershock area of the 2005 West Off Fukuoka Prefecture Earthquake (M7.0)

Cited by 15 publications

References 33 publications

QP structure of the accretionary wedge in the Kumano Basin, Nankai Trough, Japan, revealed by long-offset walk-away VSP

QP structure of the accretionary wedge in the Kumano Basin, Nankai Trough, Japan, revealed by long-offset walk-away VSP

The 3D Attenuation Structure of Deception Island (Antarctica)

Seismic attenuation tomography of the source zone of the 2016 Kumamoto earthquake (M 7.3)

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