R.W. Simpson P.A. Reasenberg R.A. Harris 1995 <p><span>Earthquakes induce changes in static stress on neighbouring faults that may delay, hasten or even trigger subsequent earthquakes</span>^1–10<span>. The length of time over which such effects persist has a bearing on the potential contribution of stress analyses to earthquake hazard assessment, but is presently unknown. Here we use an elastic half-space model</span>¹¹<span>&nbsp;to estimate the static stress changes generated by damaging (magnitude&nbsp;</span><i>M</i><span>≥5) earthquakes in southern California over the past 26 years, and to investigate the influence of these changes on subsequent earthquake activity. We find that, in the 1.5-year period following a&nbsp;</span><i>M</i><span>≥5 earthquake, any subsequent nearby&nbsp;</span><i>M</i><span>≥5 earthquake almost always ruptures a fault that is loaded towards failure by the first earthquake. After this period, damaging earthquakes are equally likely to rupture loaded and relaxed faults. Our results suggest that there is a short period of time following a damaging earthquake in southern California in which simple Coulomb failure stress models could be used to identify regions of increased seismic hazard.</span></p> application/pdf 10.1038/375221a0 en Springer Nature Influence of static stress changes on earthquake locations in southern California article