Ryoya Ikuta scite author profile

[1] We show fine-scale variations of seismic velocities and converted teleseismic waves that reveal the presence of zones of high-pressure fluids released by progressive metamorphic dehydration reactions in the subducting Philippine Sea plate in Tokai district, Japan. These zones have a strong correlation with the distribution of slow earthquakes, including long-term slow slip (LTSS) and low-frequency earthquakes (LFEs). Overpressured fluids in the LTSS region appear to be trapped within the oceanic crust by an impermeable cap rock in the fore-arc, and impede intraslab earthquakes therein. In contrast, fluid pressures are reduced in the LFE zone, which is deeper than the centroid of the LTSS, because there fluids are able to infiltrate into the narrow corner of the mantle wedge, leading to mantle serpentinization. The combination of fluids released from the subducting oceanic crust with heterogeneous fluid transport properties in the hanging wall generates variations of fluid pressures along the downgoing plate boundary, which in turn control the occurrence of slow earthquakes. Citation: Kato, A., et al. (2010), Variations of fluid pressure within the subducting oceanic crust and slow earthquakes, Geophys.

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Continuous monitoring of propagation velocity of seismic wave using ACROSS

Ikuta

2002

Geophysical Research Letters

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[1] Temporal variations in the P-and S-wave travel times were continuously monitored using ACROSS, which is a newly developed system for utilizing accurately controlled continuous sinusoids for seismic exploration. We made an experiment lasting for 15 months at a site near the Nojima fault which ruptured during the 1995 Kobe earthquake (M7.2). The elastic waves emitted from the ACROSS vibrators located at the surface were observed with seismometers at 800 m and 1700 m depth. The long-term variations of about 2 ms for both the P and S waves were observed during the 15-month experiment. The major cause of these variations is identified to be that of a near-surface property which changes the near-source vibration. The variations in the deeper structures estimated after the reduction of the near-source variation were about 0.5 ms. An S-wave delay of about 1 ms was detected due to the 2000 Western Tottori earthquake (M6.6).

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A new GPS‐acoustic method for measuring ocean floor crustal deformation: Application to the Nankai Trough

et al. 2008

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We developed a new geodetic method of monitoring crustal deformation on the ocean floor. The measurements were conducted at two sites beneath the Pacific Ocean, near the Nankai Trough, where the Philippine Sea plate subducts into the Pacific plate. The first site was at a depth of 700 m in Suruga Bay, and the second one was at a depth of 2000 m in the Kumano Basin. At each survey site, three seafloor transponders, whose positions were repetitively measured, were deployed to define a benchmark unit. An ultrasonic signal was generated from a surface vessel drifting over the benchmark unit that was transmitting and receiving the signal and the replies from the transponders. Both sound speed structure and the benchmark unit positions were determined simultaneously using a tomographic technique. We repeatedly carried out measurements over the two sites. For the Kumano Basin we made six measurements from July 2004 to August 2005. The benchmark unit location's horizontal precision was 5 cm, and its vertical precision was 10 cm. For Suruga Bay we made five measurements, and the positions were less accurate, with horizontal variation of 7 cm and vertical variation of 16 cm. We investigated the reason for the decreased precision in Suruga Bay with a numerical experiment, and the results revealed that the geometry of the measurement, that is, the vessel's path, is one of the most important variables in our method. At the Kumano Basin a 21.5‐cm southward displacement of the benchmark unit was detected just below the site before and after a large earthquake (Mw 7.5). Our observation system therefore proved itself capable of detecting seafloor crustal deformation associated with crustal activities in offshore areas.

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Source of high tsunamis along the southernmost Ryukyu trench inferred from tsunami stratigraphy

Ando

Kitamura

et al. 2018

Tectonophysics

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Ryoya Ikuta

Variations of fluid pressure within the subducting oceanic crust and slow earthquakes

Continuous monitoring of propagation velocity of seismic wave using ACROSS

A new GPS‐acoustic method for measuring ocean floor crustal deformation: Application to the Nankai Trough

Source of high tsunamis along the southernmost Ryukyu trench inferred from tsunami stratigraphy

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