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—We study the propagation of seismic ruptures along a fault surface using a fourth-order finite difference program. When prestress is uniform, rupture propagation is simple but presents essential differences with the circular self-similar shear crack models of Kostrov. The best known is that rupture can only start from a finite initial patch (or asperity). The other is that the rupture front becomes elongated in the in-plane direction. Finally, if the initial stress is sufficiently high, the rupture front in the in-plane direction becomes super-shear and the rupture front develops a couple of “ears” in the in-plane direction. We show that we can understand these features in terms of single nondimensional parameter κ that is roughly the ratio of available strain energy to energy release rate. For low values of κ rupture does not occur because Griffith's criterion is not satisfied. A bifurcation occurs when κ is larger than a certain critical value, κ c . For even larger values of κ rupture jumps to super-shear speeds. We then carefully study spontaneous rupture propagation along a long strike-slip fault and along a rectangular asperity. As for the simple uniform fault, we observe three regimes: no rupture for subcritical values of κ, sub-shear speeds for a narrow range of supercritical values of κ, and super-shear speeds for κ > 1.3κ c . Thus, there seems to be a certain universality in the behavior of seismic ruptures.
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Received August 4, 1999; revised April 4, 2000; accepted April 5, 2000
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Madariaga, R., Olsen, K. Criticality of Rupture Dynamics in 3-D. Pure appl. geophys. 157, 1981–2001 (2000). https://doi.org/10.1007/PL00001071
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DOI: https://doi.org/10.1007/PL00001071