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RSQSim. Jim Dieterich Keith Richards-Dinger. UC Riverside. Funding: USGS NEHRP SCEC. Representation of Fault Friction. Constitutive relation: State evolution: Stress evolution: Terms in red are additional ones due to normal stress variations (Linker and Dieterich, 1992)
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RSQSim Jim Dieterich Keith Richards-Dinger UC Riverside Funding: USGS NEHRP SCEC
Representation of Fault Friction • Constitutive relation: • State evolution: • Stress evolution: • Terms in red are additional ones due to normal stress variations (Linker and Dieterich, 1992) • Interaction coefficients, K, calculated from the dislocation solutions of Okada, 1992 • Tectonic stressing rates derived from backslipping the model • Numerical integration too slow for the scale of problems we would like to address
State 0: locked fault State 2: seismic slip Representation of Fault Friction • Constitutive relation: • State evolution: • Stress evolution: State 1: nucleation
Representation of Fault Friction • No predetermined failure stress or stress drop • Stress drop scales roughly as
Representation of Fault Friction • No predetermined failure stress or stress drop • Stress drop scales roughly as
Approximations to Elastodynamics Parameters that influence the rupture process: • Slip speed during coseismic slip determined from shear impedance considerations • Reduction of a on patches nearby to seismically slipping patches • Stress overshoot during ruptures
Effect of Overshoot on Rupture Characteristics Large overshoot (13%) Small overshoot (1%)
Approximations to Elastodynamics Values for rupture parameters determined by comparison with fully dynamic rupture models DYNA3D – Fully dynamic finite element simulation Propagation time 14.0 s RSQsim – Fast simulation Propagation time 14.3 s
Representation of Viscoelasticityafterslip • Rate-strengthening (a > b) patches • Approximated as always sliding at steady-state • Distributed as • Deep creeping extensions to major faults • Shallow creep on major faults • Entire creeping sections (e.g. SAF north of Parkfield) • Possibly with small imbedded stick-slip patches • More complicated mixed stick-slip and creeping areas (e.g. Hayward Fault)
Representation of Viscoelasticityafterslip Penetration of slip of large events into creeping zone
Representation of Viscoelasticityafterslip Fraction of moment release in creeping section Aftershocks
Representation of Viscoelasticityafterslip Small repeating earthquakes Simulation 1989 Loma Prieta Earthquake
Power-law temporal clustering Stacked rate of seismicity relative to mainshock origin time Decay of aftershocks follows Omori power law t -p with p = 0.77 Foreshocks (not shown) follow an inverse Omori decay with p = 0.92 Dieterich and Richards-Dinger, PAGEOPH, 2010
Power-law temporal clustering Interevent Waiting Time Distributions California Catalog 1911 – 2010.5
Power-law temporal clustering Space – Time Distributions
Earthquake cluster along San Andreas Fault M7.3 43 aftershocks in 18.2days All-Cal model – SCEC Simulator Comparison Project
Earthquake cluster along San Andreas Fault M6.9 Followed by 6 aftershocks in 4.8 minutes All-Cal model – SCEC Simulator Comparison Project
Earthquake cluster along San Andreas Fault M7.2 All-Cal model – SCEC Simulator Comparison Project
Colella et al., submitted Slow-slip events • slip ~2.3 - 4.0 cm • duration ~10-40 days • inter-event time - ~10-19 months • simultaneous slip in different areas • no Omori clustering • spontaneous segmentation
