Seismic activity near the Moriyoshi-zan volcano in Akita Prefecture, northeastern Japan: implications for geofluid migration and a midcrustal geofluid reservoir

Kosuga, Masahiro

doi:10.1186/1880-5981-66-77

Cited by 25 publications

(42 citation statements)

References 48 publications

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“…Nakajima and Hasegawa (2007) pointed out that high seismicity in this study area is probably related to locally concentrated fluids. High seismicity attributed to fluids is also pointed out elsewhere (e.g., Kosuga 2014;Terakawa et al 2013). Due to the influence of fluid, pore pressure is considered high enough to weaken the faults in this study area.…”

Section: Discussionsupporting

confidence: 55%

Complex microseismic activity and depth-dependent stress field changes in Wakayama, southwestern Japan

Maeda

Matsuzawa

Toda

et al. 2018

Earth Planets Space

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We examined the spatial relationship between seismicity and upper crustal structure in the Wakayama region, northwestern Kii Peninsula, Japan, by investigating microearthquake focal mechanisms and the local stress field. The focal mechanisms of most events studied fall into three categories: (1) normal faulting with N-S-oriented T-axes mainly occurring at shallow depths, (2) reverse faulting with E-W-oriented P-axes dominating at intermediate depths, and (3) strike-slip faulting with N-S-oriented T-axes and E-W-oriented P-axes mainly seen at greater depths. The stress field varies with depth: the shallow part is characterized by a strike-slip-type stress regime with N-S tension and E-W compression, while the deep part is characterized by an E-W compressional stress regime consistent with reverse faulting. The depth-dependent stress regime can be explained by thermal stress caused by a heat source, as expected from geophysical observations. Geologic faults, acting as weak planes, might contribute to generate shallow normal fault-type and deeper strike-slip fault-type microearthquakes.

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Section: Discussionsupporting

confidence: 55%

Complex microseismic activity and depth-dependent stress field changes in Wakayama, southwestern Japan

Maeda

Matsuzawa

Toda

et al. 2018

Earth Planets Space

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“…We also estimate the peak dynamic stress changes associated with the passage of Rayleigh and Love waves in the triggered regions from the amplitudes of the surfacewave ground velocities (e.g., Peng et al 2009). Assuming plane wave propagation for teleseismic waves, the peak dynamic stress σ d is proportional to Gu'/V ph (Jaeger and Cook 1979), where G is the shear modulus, u' is the peak particle velocity, and V ph is the phase velocity. Using a nominal G value of 30 G Pa, V ph = 4.1 km/s for the Love waves, and V ph = 3.5 km/s for the Rayleigh waves, we estimate dynamic stress change values.…”

Section: Maximum Shaking Peak Amplitudes and Dynamic Triggering Levelmentioning

confidence: 99%

Remote triggering of seismicity at Japanese volcanoes following the 2016 M7.3 Kumamoto earthquake

Enescu

Shimojo

Opris

et al. 2016

Earth Planets Space

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The M JMA 7.3 Kumamoto earthquake occurred on April 16, 2016, in the western part of Kyushu, at a depth of 12 km, on an active strike-slip fault. Here, we report on a relatively widespread activation of small remote earthquakes, which occurred as far as Hokkaido, detected by analyzing the continuous waveform data recorded at seismic stations all over Japan. Such relatively widespread remote seismicity activation, following a large inland earthquake, has not been reported before for Japan. Our analysis demonstrates that the remote events were triggered dynamically, by the passage of the surface waves from the Kumamoto earthquake. Most of the remotely triggered events in the Tohoku and Hokkaido regions, as well as close to Izu Peninsula, occur at or close to volcanoes, which suggests that the excitation of crustal fluids, by the passage of Rayleigh waves, played an important triggering role. Nevertheless, remote activation in other regions, like Noto Peninsula, occurred away from volcanoes. The relatively large-amplitude Love waves, enhanced by a source directivity effect during the Kumamoto earthquake, may have triggered seismicity on local active faults. The dynamic stresses in the areas where remote activation has been observed range from several kPa to tens of kPa, the thresholds being lower than in previous dynamic triggering cases for Japan; this might relate to a change in the crustal conditions following the 2011 M9.0 Tohoku-oki earthquake, in particular at volcanoes in NE Japan.

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“…The former, having a diameter of 10 to 20 km, resides in the lower crust. Kosuga (2014) observed the migration of seismicity for a seismic cluster near the Moriyoshi volcano in the Northeast Japan arc and identifies distinct seismic scatters above low-frequency earthquakes in the lower crust. He argues that the observed migration is associated with geofluids supplied from the uppermost mantle.…”

Section: Geofluids Detected With Magnetotelluric and Seismic Observatmentioning

confidence: 99%

Special issue ‘Geofluid processes in subduction zones and mantle dynamics’

et al. 2015

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Seismic activity near the Moriyoshi-zan volcano in Akita Prefecture, northeastern Japan: implications for geofluid migration and a midcrustal geofluid reservoir

Cited by 25 publications

References 48 publications

Complex microseismic activity and depth-dependent stress field changes in Wakayama, southwestern Japan

Complex microseismic activity and depth-dependent stress field changes in Wakayama, southwestern Japan

Remote triggering of seismicity at Japanese volcanoes following the 2016 M7.3 Kumamoto earthquake

Special issue ‘Geofluid processes in subduction zones and mantle dynamics’

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