Laboratory simulations of earthquakes show that at high slip rates, faults can weaken significantly, aiding rupture(1-3). Various mechanisms, such as thermal pressurization and flash heating, have been proposed to cause this weakening during laboratory experiments(1,4-6,) yet the processes that aid fault slip in nature remain unknown. Measurements of seismic radiation during an earthquake can be used to estimate the frictional work associated with fault weakening, known as an event's fracture energy(7-9). Here we compile new and existing(8,9) measurements of fracture energy for earthquakes globally that vary in size from borehole microseismicity to great earthquakes. We observe a distinct transition in howfracture energy scales with event size, which implies that faults weaken differently during small and large earthquakes, and earthquakes are not self-similar. We use an elastodynamic numerical model of earthquake rupture to explore possible mechanisms. We find that thermal pressurization of pore fluid by the rapid shear heating of fault gouge can account for the observed scaling of fracture energy in small and large earthquakes, over seven orders of fault slip magnitude. We conclude that thermal pressurization is a widespread and prominent process for fault weakening.

• 出版日期2015-11