Abstract
We propose a new waveform inversion method to estimate the 2D S-wave velocity structure of deep sedimentary layers using broadband Love waves. As a preprocessing operation in our inversion scheme, we decompose earthquake observation records into velocity waveforms for periods of 1 s each. Then, we include in the inversion only those periods for which the assumption of 2D propagation holds, which we propose to determine through a principal component analysis. A linearized iterative inversion analysis for the selected Love wave segments filtered for periods of 1 s each allows a detailed estimation of the boundary shapes of interfaces over the seismic bedrock with an S-wave velocity of approximately 3 km/s. We demonstrate the effectiveness of the technique with applications to observed seismograms in the Kanto Plain, Japan. The differences between the estimated and existing velocity structure models are remarkable at the basin edges. Our results show remarkable differences from previous existing structural models, particularly near the basin edges while being in good agreement with the surface geology. Since a subsurface structure at a basin edge strongly affects the earthquake ground motions in a basin with the generation of surface waves, our method can provide a detailed model of a complex S-wave velocity structure at an edge part for strong ground motion prediction.
Highlights
Predicting earthquake ground motion using a theoretical approach such as a FD simulation requires an appropriate model of the subsurface S-wave and P-wave velocities, density, and attenuation factors
Earthquake records Here, we describe the characteristics of long-period earthquake ground motion records acquired during a moderate-size MJ 6.4 (JMA magnitude) earthquake in the Kanto Plain, Japan, that we will subject later to waveform inversion
As a preprocessing operation in our inversion scheme, we decompose earthquake observation records into velocity waveforms for periods of 1 s each to confirm the assumption of 2D propagations of the Love waves with a principal component analysis of the horizontal ground motions
Summary
Predicting earthquake ground motion using a theoretical approach such as a FD simulation requires an appropriate model of the subsurface S-wave and P-wave velocities, density, and attenuation factors. Kasamatsu et al Earth, Planets and Space (2021) 73:17 layer with an S-wave velocity of 0.5 km/s and shallower than that simultaneously, which had ever been modeled separately. These velocity models have been validated by comparing simulated earthquake ground motions with observed motions for moderate-size seismic events. Kawase (1996) showed that a large amplitude area was caused by the constructive interference of direct S-waves and basin-induced Rayleigh waves generated at a basin edge during the 1995 Hyogo-ken Nanbu earthquake through strong ground motion simulations. The existing 3D models may lack detailed features in the edge parts because of difficulties in modeling their complicated shapes
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