A High Density Sampling K-Ar Dating of the Kinpu-San Plutonic Body and the Initiation of the Philippine Sea Plate Subduction.

SUMMARY The evolution of the Philippine Sea Plate (PSP) since Jurassic is one of the key issues in the dynamics of lithosphere and mantle. The related studies benefited mostly from seismic tomography which provides velocity structures in the upper mantle. However, the upper-mantle structure is not well resolved compared to the continental areas due to the lack of seismic data in the Philippine Sea. We employ a 3-D gravity inversion constrained by an initial model based on the S-wave tomography (SL2013sv; Schaeffer & Lebedev 2013) to image the density structure of the upper mantle of the PSP and adjacent region. The resulting model shows a three-layer pattern of vertical high-low-high density variation in the upper mantle under the PSP. The thin high-density layer evidences for strong oceanic lithosphere in the West Philippine Sea. The relatively low dense mantle located below the PSP possibly originates from the asthenosphere. The PSP differs from the Pacific and the Indian-Australian plates in the whole depth range, while its structure is similar to the eastern Eurasian and Sunda plates. In the depth range, 200–300 km, the relative high-density zone beneath PSP extends to the Sunda Plate and to the eastern Eurasian Plate. We further estimated the conversion factor of our density model and the velocity model (SL2013sv; Schaeffer & Lebedev 2013) in order to locate the changes of compositional effects in the upper mantle. The negative conversion factor indicates that the compositional changes primarily affect the density anomalies beneath the PSP. We, therefore, describe the layered density structures as ‘sandwich’ pattern, which is unique and different from adjacent regions.

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Repeating earthquake activities associated with the Philippine Sea plate subduction in the Kanto district, central Japan: A new plate configuration revealed by interplate aseismic slips

Tectonophysics ◽

10.1016/j.tecto.2005.06.013 ◽

2006 ◽

Vol 417 (1-2) ◽

pp. 101-118 ◽

Cited By ~ 52

Author(s):

Hisanori Kimura ◽

Keiji Kasahara ◽

Toshihiro Igarashi ◽

Naoshi Hirata

Keyword(s):

Philippine Sea Plate ◽

Central Japan ◽

Philippine Sea ◽

Kanto District ◽

Repeating Earthquake ◽

Plate Subduction

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Two‐Dimensional Thermal Modeling of the Philippine Sea Plate Subduction in Central Japan: Implications for Gap of Low‐Frequency Earthquakes and Tectonic Tremors

Journal of Geophysical Research Solid Earth ◽

10.1029/2018jb017068 ◽

2019 ◽

Vol 124 (7) ◽

pp. 6848-6865 ◽

Cited By ~ 3

Author(s):

Nobuaki Suenaga ◽

Shoichi Yoshioka ◽

Takumi Matsumoto ◽

Vlad C. Manea ◽

Marina Manea ◽

...

Keyword(s):

Thermal Modeling ◽

Low Frequency ◽

Philippine Sea Plate ◽

Two Dimensional ◽

Central Japan ◽

Philippine Sea ◽

Plate Subduction

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Configuration and structure of the Philippine Sea Plate off Boso, Japan: constraints on the shallow subduction kinematics, seismicity, and slow slip events

Earth Planets and Space ◽

10.1186/s40623-019-1090-y ◽

2019 ◽

Vol 71 (1) ◽

Cited By ~ 2

Author(s):

Aki Ito ◽

Takashi Tonegawa ◽

Naoki Uchida ◽

Yojiro Yamamoto ◽

Daisuke Suetsugu ◽

...

Keyword(s):

Receiver Function ◽

Function Analysis ◽

Philippine Sea Plate ◽

Slow Slip ◽

Low Velocity ◽

Slow Slip Events ◽

Philippine Sea ◽

Receiver Function Analysis ◽

Eastern Edge ◽

Upper Boundary

Abstract We applied tomographic inversion and receiver function analysis to seismic data from ocean-bottom seismometers and land-based stations to understand the structure and its relationship with slow slip events off Boso, Japan. First, we delineated the upper boundary of the Philippine Sea Plate based on both the velocity structure and the locations of the low-angle thrust-faulting earthquakes. The upper boundary of the Philippine Sea Plate is distorted upward by a few kilometers between 140.5 and 141.0°E. We also determined the eastern edge of the Philippine Sea Plate based on the delineated upper boundary and the results of the receiver function analysis. The eastern edge has a northwest–southeast trend between the triple junction and 141.6°E, which changes to a north–south trend north of 34.7°N. The change in the subduction direction at 1–3 Ma might have resulted in the inflection of the eastern edge of the subducted Philippine Sea Plate. Second, we compared the subduction zone structure and hypocenter locations and the area of the Boso slow slip events. Most of the low-angle thrust-faulting earthquakes identified in this study occurred outside the areas of recurrent Boso slow slip events, which indicates that the slow slip area and regular low-angle thrust earthquakes are spatially separated in the offshore area. In addition, the slow slip areas are located only at the contact zone between the crustal parts of the North American Plate and the subducting Philippine Sea Plate. The localization of the slow slip events in the crust–crust contact zone off Boso is examined for the first time in this study. Finally, we detected a relatively low-velocity region in the mantle of the Philippine Sea Plate. The low-velocity mantle can be interpreted as serpentinized peridotite, which is also found in the Philippine Sea Plate prior to subduction. The serpentinized peridotite zone remains after the subduction of the Philippine Sea Plate and is likely distributed over a wide area along the subducted slab.

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