Your search keyword '"Muramoto, Tomoya"' showing total 2 results

1. Strain and Stress Accumulation in Viscoelastic Splay Fault and Subducting Oceanic Crust.

Author

Muramoto, Tomoya, Ito, Yoshihiro, Miyakawa, Ayumu, and Furuichi, Noriyuki

Subjects

*OCEANIC crust, *STRAINS & stresses (Mechanics), *STRAIN rate, *VISCOSITY, *STRESS relaxation (Mechanics)

Abstract

This study constructs a model to represent the strain–stress field surrounding a splay fault and demonstrates the accumulation processes of both strain and stress around the splay fault. We consider the case of multiple fault dislocations, construct the model as a function of the effective viscosity in the media, and investigate the influence of the effective viscosity on the strain and stress accumulation patterns. The results show that the strain and stress tend to accumulate in the splay fault and the subducting oceanic crust, and the rate of accumulation varies with the effective viscosity. The accumulation and relaxation of strain and stress are simultaneous, and the slower the effective viscosity, the slower the accumulation rate. We discuss the relationship between the splay faults, fluid, and intraslab earthquakes. Finally, the possibility that effective viscosity may contribute to the mode of occurrence of intraslab earthquakes at the Hikurangi subduction margin is discussed. Plain Language Summary: We construct a simple model to explain the evolution of strain and stress over time in a subduction margin. The model constructed in this study is the case where a fault branches from a plate boundary. We investigate the influence of the effective viscosity of its constituents on the temporal evolution of strain and stress. The results show that the rate of strain and stress accumulation varies with the effective viscosity. Our result may suggests the influence of the effective viscosity on the source distribution of the microearthquakes observed at the Hikurangi subduction margin. Key Points: Temporal evolution of strain and stress caused by the dislocation of tri‐materials with different effective viscosities is calculatedStrain and stress accumulation rate depends on the effective viscosityStrain and stress accumulated at the multiple fault edge strongly influence the stress perturbations in the subducting oceanic crust [ABSTRACT FROM AUTHOR]

Published

2023

2. Viscoelasticity modeling of clay minerals by dynamic viscoelasticity measurement and its implications for earthquake faulting.

Author

Muramoto, Tomoya, Ito, Yoshihiro, Miyakawa, Ayumu, and Furuichi, Noriyuki

Subjects

*EARTHQUAKES, *MINERAL properties, *RHEOLOGY, *CLAY minerals, *VISCOELASTICITY, *FREQUENCIES of oscillating systems, *SMECTITE

Abstract

Slip on clay fault planes at shallow depths in the seismogenic zone could be controlled by their rheology as well as their frictional properties; however, the rheological nature of clay faults is still an open question. Investigating the rheological properties of clay minerals is essential for understanding and modeling shallow earthquake faulting. Here, we perform dynamic viscoelasticity measurements on three clay minerals, namely kaolinite, illite, and smectite, wetted with water using a custom-made high pressure, high temperature rheometer. Our results confirm that the rheological properties resulting from the microstructure of clay minerals depend on the oscillation frequency, oscillation amplitude, temperature, and amount of water contained. In addition, the rheological properties vary systematically with the type of clay mineral. This suggests that the viscoelastic behavior of earthquake faults varies with the type of clay minerals present. • Dynamic viscoelasticity measurements are performed on clay minerals under high temperature and high pressure. • Dynamic viscoelasticity of clay minerals depends on oscillation frequency, oscillation amplitude, temperature and the type of mineral. [ABSTRACT FROM AUTHOR]

Published

2024