Abstract
The 2011 Tohoku-Oki earthquake (Mw 9.0) produced a fault rupture that extended to the toe of the Japan Trench. The deformation and frictional properties beneath the forearc are keys that can help to elucidate this unusual event. In the present study, to investigate the frictional properties of the shallow part of the plate boundary, we applied the critically tapered Coulomb wedge theory to the Japan Trench and obtained the effective coefficient of basal friction and Hubbert-Rubey pore fluid pressure ratio (λ) of the wedge beneath the lower slope. We extracted the surface slope angle and decollement dip angle (which are the necessary topographic parameters for applying the critical taper theory) from seismic reflection and refraction survey data at 12 sites in the frontal wedges of the Japan Trench. We found that the angle between the decollement and back-stop interface generally decreases toward the north. The measured taper angle and inferred effective friction coefficient were remarkably high at three locations. The southernmost area, which had the highest coefficient of basal friction, coincides with the area where the seamount is colliding offshore of Fukushima. The second area with a high effective coefficient of basal friction coincides with the maximum slip location during the 2011 Tohoku-Oki earthquake. The area of the 2011 earthquake rupture was topographically unique from other forearc regions in the Japan Trench. The strain energy accumulation near the trench axis may have proceeded because of the relatively high friction, and later this caused a large slip and collapse of the wedge. The location off Sanriku, where there are neither seamount collisions nor rupture propagation, also has a high coefficient of basal friction. The characteristics of the taper angle, effective coefficient of basal friction, and pore fluid pressure ratio along the Japan Trench presented herein may contribute to the understanding of the relationship between the geometry of the prism and the potential for generating seismo-tsunamigenic slips.
Highlights
The 2011 Tohoku-Oki earthquake (Mw 9.0) produced a fault rupture that extended to the shallow portion of the Japan Trench
The area of the 2011 earthquake rupture was topographically unique from other forearc regions in the Japan Trench
By assuming that (1) the tip of the wedge is tapered, (2) the sediments added to the prism are non-viscous, and (3) the internal stress is always at the critical state just before failure, the taper angle (α + β) of the wedge is controlled by the relative strengths of the wedge material and basal fault, i.e., the coefficient of internal friction averaged over the wedge (μ), the the pore fluid pressure ratio within effective coefficient of basal friction
Summary
The 2011 Tohoku-Oki earthquake (Mw 9.0) produced a fault rupture that extended to the shallow portion of the Japan Trench. Kimura et al (2012) focused on seismic reflection data along a seismic transect of the ruptured area at the Japan Trench, and they measured the taper angle and estimated the effective coefficient of basal friction at the plate boundary by using the critically tapered Coulomb wedge theory (Davis et al 1983; Dahlen 1984). We used 12 profiles (Figure 1) to calculate the effective coefficient of basal friction at the plate boundary with the intent of better understanding the along-trench variation (e.g., Fagereng 2011). From these results, we discuss the relationship between the geometry of the prism and tsunamigenic slip in the Japan Trench
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