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Inherent Mechanism Determining Scaling Properties of Fault Constitutive Laws

Inherent Mechanism Determining Scaling Properties of Fault Constitutive Laws. Mitsuhiro Matsu’ura Department of Earth and Planetary Science Graduate School of Science The University of Tokyo. Progress in the Physics of Earthquake Generation in 1990s.

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Inherent Mechanism Determining Scaling Properties of Fault Constitutive Laws

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  1. Inherent Mechanism Determining Scaling Properties of Fault Constitutive Laws Mitsuhiro Matsu’ura Department of Earth and Planetary Science Graduate School of Science The University of Tokyo

  2. Progress in the Physics of Earthquake Generation in 1990s ■Introduction of Laboratory-based Fault Constitutive Laws as a Basic Equation Governing Earthquake Rupture - Slip-weakening law (e.g., Ohnaka et al., 1987; Matsu’ura et al, 1992) - Rate- and State-dependent law (e.g., Dieterich, 1979; Ruina, 1983) - Slip- and time-dependent law (Aochi & Matsu’ura, 1999, 2002) - Scale-dependence of the critical weakening displacement Dc ■Quantitative Description of Tectonic Loading Driven by Plate Motion - Viscous drag at the base of the lithosphere (base-loading) - Dislocation pile-ups at the edge of a locked portion (edge-loading) - Mathematical formulation of elastic/viscoelastic slip-response functions

  3. Basic Equations Governing Earthquake Generation Cycles Slip Response Function Shear stress change due to slip perturbation Boundary conditions to be satisfied Fault Constitutive Law Change in fault constitutive relation with slip and time Total slip at a plate interface Relative Plate Motion

  4. Energy Balance for Spontaneous Rupture Growth y x

  5. Dc ≈ Slip-weakening Constitutive Law : Characteristic weakening displacement Upper fractal limit (b) Fractality of rock surfaces [Power, et al., 1987] (a) Observed constitutive relation [Ohnaka, et al., 1987] (c) Change in surface topography with fault slip [Matsu’ura, et al., 1992] (d) Theoretical constitutive relation [Matsu’ura, et al., 1992]

  6. Quasi-static Rupture Nucleation Process Governed by the Slip-weakening Constitutive Law Asperity 3D plot of fault constitutive relations [Matsu’ura, et al., 1992] t :Shear strength. w: Fault slip. x: Distance along the fault. Quasi-static shear stress (a) and fault slip (b) changes with time [Matsu’ura, et al., 1992]

  7. Transition from Quasi-static Nucleation to Dynamic Rupture From observation and simulation Fundamental scaling law Shear stress change during dynamic rupture of an asperity and the subsequent major event [Shibazaki and Matsu’ura, 1992] Change in fault slip (thick line) and slip velocity (thin line) with time [Shibazaki and Matsu’ura, 1992]

  8. The Entire Earthquake Generation Process

  9. Restoration of Fault Strength Log t-healingduring stationary contact and slip-velocity weakening in steady-state slip (b) Evolution of surface topography during stationary contact [Aochi and Matsu’ura, 2002] Characteristic healing time: (a) Change in fault strength with time in stationary contact [Dieterich, 1972] (c) Slip-velocity dependence of fault strength in steady-state slip [Dieterich, 1978]

  10. Slip- and Time-dependent Fault Constitutive Law [Aochi and Matsu’ura, 1999, 2002] Definition of fault strength and the evolution equation of surface topography Physical quantities and parameters Inherent Mechanisms: - Slip weakening due to abrasion of fractal rock surfaces - Strength restoration due to adhesion and adhesive ware

  11. The case of high-speed slip --> Slip weakening Characteristic weakening displacement: The case of stationary contact --> Log t healing Characteristic healing time: The case of steady-state slip --> Slip-velocity weakening Constitutive Properties of the Slip- and Time-Dependent Law

  12. Evolution Equation of the State Variable in a Rate- and State-Dependent Law (NielsenI et al., 2000) The evolution equation of the slip- and time-dependent law: For surface asperities with a characteristic wavelength ( ) : with ; Characteristic displacement for slip-weakening ; Characteristic time for healing

  13. Simulation of Complete Earthquake Generation Cycles Shear StressSlip Deficits Shear Stress Fault Slip (b) Initial stress distribution 0 Shear Stress (MPa) 3 0 Slip Deficits (m) 2 (a) Quasi-static stress accumulation (c) Dynamic rupture propagation Hashimoto, Fukuyama & Matsu’ura

  14. Evolution of Fault Constitutive Relation During One Earthquake Cycle The critical weakening displacement Dc gradually increases with contact time t. The gradual increase of Dc with contact time t can be attributed to the gradual recovery of larger-scale fractal structure of damaged fault through adhesion of surface asperities in direct contact. Change in constitutive relation with time after a large earthquake: rapid restoration of peak strength and gradual increase of critical weakening displacement Dc [Hashimoto and Matsu’ura, 2002].

  15. Scale dependence of Dc: Scale dependence of healing time: A Realistic Image of Fault Strength Restoration after the Occurrence of a Large Earthquake (a) An image of the heterogeneous fault with a hierarchic fractal structure in Dc. (b) A schematic diagram showing restoration of fault constitutive properties after a large event.

  16. Conclusions Fault constitutive laws play the role of an interface between microscopic processes in fault zones and macroscopic processes of a fault system. Macroscopic viewpoints: - Functional relation among shear strength, fault slip, and contact time - Basic equation governing earthquake rupture / Physics - Boundary condition in continuum mechanics / Mathematics Microscopic viewpoints: - Energy balance equation for a fault zone with fractal internal structure - Mechanical energy dissipation in fault zones / Slip-weakening - Restoration of fractal structure in fault zones / Strengthening in contact - Integration of microscopic physicochemical processes in fault zones

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