Your search keyword '"Kaneda, Yoshiyuki"' showing total 7 results

1. Introduction to ocean floor networks and their scientific application.

Author

Kaneda, Yoshiyuki

Subjects

*OCEAN bottom, *MARINE geophysics

Abstract

An introduction is presented in which the editor outlines the theme of the issue focusing on the scientific application of ocean floor networks.

Published

2014

2. Seismic activity beneath the Nankai trough revealed by DONET ocean-bottom observations.

Author

Nakano, Masaru, Nakamura, Takeshi, Kamiya, Shin-ichiro, and Kaneda, Yoshiyuki

Subjects

SEISMIC waves, OCEAN bottom, EARTHQUAKES, MARINE geophysics

Abstract

We conducted a detailed investigation of seismic activity from January 2011 to February 2013 along the Nankai trough off the Kii Peninsula, central Japan, by using data obtained from the DONET ocean-bottom observation network. The hypocenters are mostly within the subducting Philippine Sea (PHS) plate, although a few are along the plate boundary or in the sedimentary wedge below the Kumano forearc basin. The seismic activity can be separated into events above and below 20 km depth, which corresponds approximately to the Moho. The hypocenter distributions are distinctly different for these groups. The seismic activity in the oceanic crust can be further separated into three clusters. Most of the seismic activity recorded in our data represents aftershocks of the 2004 off the Kii Peninsula earthquakes ( M = 7.1, 7.4, and 6.5), which occurred in the PHS plate. The hypocenter distribution in the oceanic crust correlates well with the location of the Paleo-Zenisu ridge, which is formed by a chain of seamounts that is subducting beneath the forearc basin. The hypocenters in the uppermost mantle are aligned on a plane dipping to the southeast, consistent with the existence of a thrust fault cutting through the lithosphere of the oceanic plate. The focal mechanisms of the earthquakes show that the axis of compressive stress in the PHS plate is oriented N-S, almost perpendicular to the direction of plate convergence, indicating a complex tectonic regime in this region. These results suggest that intraplate shortening may be occurring in the subducting oceanic plate. [ABSTRACT FROM AUTHOR]

Published

2014

3. The detectability of shallow slow earthquakes by the Dense Oceanfloor Network system for Earthquakes and Tsunamis (DONET) in Tonankai district, Japan.

Author

Ariyoshi, Keisuke, Nakata, Ryoko, Matsuzawa, Toru, Hino, Ryota, Hori, Takane, Hasegawa, Akira, and Kaneda, Yoshiyuki

Subjects

EARTHQUAKES, OCEAN bottom, TSUNAMIS, COMPUTER simulation, MARINE geophysics

Abstract

In order to understand the characteristics of shallow very low-frequency (VLF) events as revealed by recent ocean-floor observation studies, we perform a trial simulation of earthquake cycles in the Tonankai district by taking the characteristics of the 1944 Tonankai earthquake and assuming that slow earthquakes occur on numerous small asperities. Our simulation results show that the increase of moment release rate of shallower VLF events in the pre-seismic stage of a megathrust earthquake is higher than that of deeper VLF events. This increase may make leveling change due to VLF swarms detectable at Dense Oceanfloor Network system for Earthquakes and Tsunamis (DONET). We also introduce the time series of hydraulic pressure data at DONET, comparing with the leveling change expected from our numerical simulation. Since leveling change due to shallower VLF swarms is so local as to be incoherent, removal of the moving-averaged data from the data stacked by four nearby observation points in the same node may be useful to detect the short-term local leveling change. [ABSTRACT FROM AUTHOR]

Published

2014

4. Anomalously large seismic amplifications in the seafloor area off the Kii peninsula.

Author

Nakamura, Takeshi, Nakano, Masaru, Hayashimoto, Naoki, Takahashi, Narumi, Takenaka, Hiroshi, Okamoto, Taro, Araki, Eiichiro, and Kaneda, Yoshiyuki

Subjects

SEISMIC waves, OCEAN bottom, EARTHQUAKES, MARINE geophysics

Abstract

Seismic wave amplifications were investigated using strong-motion data obtained from the ground's surface (K-net) on the Kii peninsula (southwestern Japan) and from the network of twenty seismic stations on the seafloor (DONET) located off the peninsula near the Nankai trough. Observed seismograms show that seismic signals at DONET stations are significantly larger than those at K-net stations, independent of epicentral distances. In order to investigate the cause of such amplifications, seismic wavefields for local events were simulated using the finite-difference method, in which a realistic 3D velocity structure in and around the peninsula was incorporated. Our simulation results demonstrate that seismic waves are significantly amplified at DONET stations in relation to the presence of underlying low-velocity sediment layers with a total thickness of up to 10 km. Our simulations also show considerable variations in the degree of amplification among DONET stations, which is attributed to differences in the thickness of the sediment layers. The degree of amplification is relatively low at stations above thin sediment layers near the trough axis, but seismic signals are much more amplified at stations closer to the Kii peninsula, where sediment layers are thicker than those at the trough axis. Simulation results are consistent with observations. This study, based on seafloor observations and simulations, indicates that because seismic signals are amplified due to the ocean-specific structures, the magnitude of earthquakes would be overestimated if procedures applied to data observed at land stations are used without corrections. [ABSTRACT FROM AUTHOR]

Published

2014

5. Numerical forecasting of the time interval between successive M8 earthquakes along the Nankai Trough, southwest Japan, using ocean bottom cable network data.

Author

Hori, Takane, Hyodo, Mamoru, Miyazaki, Shin'ichi, and Kaneda, Yoshiyuki

Subjects

EARTHQUAKE prediction, CABLE structures, COMPUTER simulation, MARINE geophysics

Abstract

One possible approach to estimating the time interval between large-scale Tōnankai (Tōkai) and Nankai earthquakes on the Japan arc is sequential assimilation of crustal deformation data. We conducted numerical modeling of sequential assimilation using surface deformation calculated from earthquake generation cycle simulations along the Nankai Trough. To account for observation noise, we used measured ocean bottom pressure gauge data, excluding tidal modulation, from a station on the ocean bottom cable network Dense Oceanfloor Network System for Earthquakes and Tsunamis in the Kumano basin. We used sequential importance sampling as our data assimilation method. We found that as the amount of data increased, the estimated time interval between the Tōnankai and Nankai earthquakes approached the 'true' observed interval. In addition, the noise in the pressure gauge data was sufficiently small that simulated crustal deformation patterns could be distinguished for different time intervals. [ABSTRACT FROM AUTHOR]

Published

2014

6. New buoy observation system for tsunami and crustal deformation.

Author

Takahashi, Narumi, Ishihara, Yasuhisa, Ochi, Hiroshi, Fukuda, Tatsuya, Tahara, Jun'ichiro, Maeda, Yosaku, Kido, Motoyuki, Ohta, Yusaku, Mutoh, Katsuhiko, Hashimoto, Gosei, Kogure, Satoshi, and Kaneda, Yoshiyuki

Subjects

TSUNAMIS, PRESSURE sensors, OCEAN currents, ACOUSTIC transducer arrays, MARINE geophysics

Abstract

We have developed a new system for real-time observation of tsunamis and crustal deformation using a seafloor pressure sensor, an array of seafloor transponders and a Precise Point Positioning (PPP ) system on a buoy. The seafloor pressure sensor and the PPP system detect tsunamis, and the pressure sensor and the transponder array measure crustal deformation. The system is designed to be capable of detecting tsunami and vertical crustal deformation of ±8 m with a resolution of less than 5 mm. A noteworthy innovation in our system is its resistance to disturbance by strong ocean currents. Seismogenic zones near Japan lie in areas of strong currents like the Kuroshio, which reaches speeds of approximately 5.5 kt (2.8 m/s) around the Nankai Trough. Our techniques include slack mooring and new acoustic transmission methods using double pulses for sending tsunami data. The slack ratio can be specified for the environment of the deployment location. We can adjust slack ratios, rope lengths, anchor weights and buoy sizes to control the ability of the buoy system to maintain freeboard. The measured pressure data is converted to time difference of a double pulse and this simple method is effective to save battery to transmit data. The time difference of the double pulse has error due to move of the buoy and fluctuation of the seawater environment. We set a wire-end station 1,000 m beneath the buoy to minimize the error. The crustal deformation data is measured by acoustic ranging between the buoy and six transponders on the seafloor. All pressure and crustal deformation data are sent to land station in real-time using iridium communication. [ABSTRACT FROM AUTHOR]

Published

2014

7. Near-field tsunami amplification factors in the Kii Peninsula, Japan for Dense Oceanfloor Network for Earthquakes and Tsunamis (DONET).

Author

Baba, Toshitaka, Takahashi, Narumi, and Kaneda, Yoshiyuki

Subjects

TSUNAMIS, EARTHQUAKES, MARINE geophysics, HYDROSTATIC pressure

Abstract

We investigated the correlation between coastal and offshore tsunami heights by using data from the Dense Oceanfloor Network for Earthquakes and Tsunamis (DONET) observational array of ocean-bottom pressure gauges in the Nankai trough off the Kii Peninsula, Japan. For near-field earthquakes, hydrostatic pressure changes may not accurately indicate sea surface fluctuations, because ocean-bottom pressure gauges are simultaneously displaced by crustal deformation due to faulting. To avoid this problem, we focused on the average waveform of the absolute value of the hydrostatic pressure changes recorded at all the DONET stations during a tsunami. We conducted a Monte Carlo tsunami simulation that revealed a clear relationship between the average waveforms of DONET and tsunami heights at the coast. This result indicates the possibility of accurate real-time prediction of tsunamis by use of arrays of ocean-bottom pressure gauges. [ABSTRACT FROM AUTHOR]

Published

2014