Rapid Normal Stress Oscillations Cause Weakening and Anelastic Dilation in Gouge‐Bearing Faults

Fault normal stress (σn) changes dynamically during earthquakes. However, the impact of these changes on fault strength is poorly understood. We explore the effects of rapidly varying σn by conducting rotary‐shear experiments on simulated fault gouges at 1 μm/s, under well‐drained, hydrothermal conditions. Our results show both elastic and anelastic (time‐dependent but recoverable) changes in gouge layer thickness in response to step changes and sinusoidal oscillations in σn. In particular, we observe dilation associated with marked weakening during ongoing σn‐oscillations at frequencies >0.1 Hz. Moreover, recovery of shear stress after such oscillations is accompanied by transient (anelastic) compaction. We propose a microphysically based friction model that explains most of the observations made, including the effects of temperature and step versus sinusoidal perturbation modes. Our results highlight that σn‐oscillations above a specific frequency threshold, controlled by the loading regime and frictional properties of the fault, may enhance seismic hazards. Plain Language Summary Faults in the crust sometimes experience rapid stress changes, caused by nearby or remote earthquakes, by seasonal impoundment and discharge of reservoirs, by hydrocarbon or geothermal energy production, or by reservoir stimulation. The impact of these stress changes on the earthquake potential of faults is poorly understood. This study explores such effects through laboratory experiments on simulated faults under upper crustal PT conditions, perturbing the normal stress on the fault in various ways. Our results show that the shear stress supported by the fault, and the fault thickness, respond instantly to normal stress changes, followed by a transient evolution. In particular, we observed dilation (fault‐normal expansion) associated with marked weakening during fast oscillation. We propose a micromechanical model that can qualitatively explain the general experimental observations. Our results indicate that varying the normal stress on a fault at frequencies above a specific threshold may enhance seismic hazard. Key Points We observed dynamic weakening and dilation of shearing gouges subjected to rapid oscillations in normal stress Fault compaction/dilation explains the shear stress evolution in response to different modes of normal stress perturbation We propose a micromechanical model for gouge friction under time‐variable normal stress conditions