Slip-weakening distance in dynamic rupture of in-slab normal-faulting earthquakes.

We estimate the critical slip-weakening distance on in-slab earthquake faults in a subduction zone, by applying a recent approach proposed by us. This approach is to find a relation between the breakdown time of shear stress , the time of peak slip velocity , and the slip-weakening distance from the time histories of shear stress, slip and slip velocity at each point on the fault. The previous results show that at can be well approximated by at for faults even with a heterogeneous stress drop distribution, except at locations near barriers and fault edges. We apply the above method to three large in-slab, normal-faulting earthquakes in the Mexican subduction zone. To do this, we calculate the spatial distribution of slip-velocity functions and final slip from kinematic waveform inversion of strong-motion and teleseismic records, and the stress history and final stress change from dynamic rupture calculations. By integrating the slip-velocity functions obtained from the inversion, from the rupture arrival time to the time of peak slip velocity, we obtain slip at and then correct it for at through dynamic calculations. We also estimate the lowest resolvable limit and probable errors of from the slip-velocity functions, and its upper bound from a theoretical constraint between the dynamic stress drop and . We found that the slip-weakening distance estimated in the frequency band between 0.05 and 0.5 Hz ranges between 40 and 120 cm on the in-slab fault of the 1999 Oaxaca earthquake . The largest is detected in the central fault and in part of the deeper sections, and in the zone around the hypocentre ranges between 50 and 70 cm. The estimated values appear to be less depth-dependent but are rather more dependent on the local maximum slip. This possible slip dependence might be interpreted by the degree of fault roughness, in addition to stress heterogeneities. The fracture energy G in the central section and in the hypocentral zone are roughly estimated to be of the order of 10–15 and 5–8 MJ m⁻², respectively. Both of the estimated and G values are somewhat larger than those on the vertical fault of two recent, shallow strike-slip earthquakes in western Japan. [ABSTRACT FROM AUTHOR]