Subduction megathrust slip speeds range from slow creep at plate convergence rates (centimetres per year) to seismic slip rates (metres per second) in the largest earthquakes on Earth. The deformation mechanisms controlling whether fast slip or slow creep occurs, however, remain unclear. Here, we present evidence that pressure solution creep (fluid-assisted stress driven mass transfer) is an important deformation mechanism in megathrust faults. We quantify megathrust strength using a laboratory-constrained microphysical model for fault friction, involving viscous pressure solution and frictional sliding. We find that at plate-boundary deformation rates, aseismic, frictional-viscous flow is the preferred deformation mechanism at temperatures...
Recent friction experiments carried out under upper crustal P–T conditions have shown that microstru...
Pore pressure is an important factor in controlling the slip instability of faults and thus the gene...
Establishing a constitutive law for fault friction is a crucial objective of earthquake science. How...
Subduction megathrust slip speeds range from slow creep at plate convergence rates (centimetres per ...
Active faults in the upper crust can either slide steadily by aseismic creep, or abruptly causing ea...
Active faults in the upper crust can either slide steadily by aseismic creep, or abruptly causing ea...
A microphysical model is developed for the steady state frictional behavior of illite-quartz fault g...
Subduction zone megathrusts generate the largest earthquakes and tsunamis known. Understanding and m...
Subduction megathrusts develop the largest earthquakes, often close to large populationcenters. Unde...
To understand the temperature/depth distribution of destructive earthquakes in subduction megathrust...
It is widely recognized that the significant increase of M > 3.0 earthquakes in Western Canada and t...
Recent friction experiments carried out under upper crustal P–T conditions have shown that microstru...
Pore pressure is an important factor in controlling the slip instability of faults and thus the gene...
Establishing a constitutive law for fault friction is a crucial objective of earthquake science. How...
Subduction megathrust slip speeds range from slow creep at plate convergence rates (centimetres per ...
Active faults in the upper crust can either slide steadily by aseismic creep, or abruptly causing ea...
Active faults in the upper crust can either slide steadily by aseismic creep, or abruptly causing ea...
A microphysical model is developed for the steady state frictional behavior of illite-quartz fault g...
Subduction zone megathrusts generate the largest earthquakes and tsunamis known. Understanding and m...
Subduction megathrusts develop the largest earthquakes, often close to large populationcenters. Unde...
To understand the temperature/depth distribution of destructive earthquakes in subduction megathrust...
It is widely recognized that the significant increase of M > 3.0 earthquakes in Western Canada and t...
Recent friction experiments carried out under upper crustal P–T conditions have shown that microstru...
Pore pressure is an important factor in controlling the slip instability of faults and thus the gene...
Establishing a constitutive law for fault friction is a crucial objective of earthquake science. How...