Abstract
The surface morphology of faults controls the spatial anisotropy of their frictional properties and hence their mechanical stability. Such anisotropy is only rarely studied in seismology models of fault slip, although it might be paramount to understand the seismic rupture in particular areas, notably where slip occurs in a direction different from that of the main striations of the fault. To quantify how the anisotropy of fault surfaces affects the friction coefficient during sliding, we sheared synthetic fault planes made of plaster of Paris. These fault planes were produced by 3D-printing real striated fault surfaces whose 3D roughness was measured in the field at spatial scales from millimeters to meters. Here, we show how the 3D-printing technology can help for the study of frictional slip. The results show that fault anisotropy controls the coefficient of static friction, with μS//, the friction coefficient along the striations being three to four times smaller than μS⊥, the friction coefficient along the orientation perpendicular to the striations. This is true both at the meter and the millimeter scales. The anisotropy in friction and the average coefficient of static friction are also shown to decrease with the normal stress applied to the faults, as a result of the increased surface wear under increased loading.
Highlights
Faults in the Earth’s crust are complex systems along which earthquakes nucleate and propagate [e.g., Wibberley et al (2008)]
One can observe the strong anisotropy of the coefficient of static friction, with the maximum value of σS being about four times larger than its minimum for Sm and about three times larger for Smm
The present study focuses on the measurement of the coefficient of static friction and on its anisotropy, but we suggest that our 3Dprint–based set-up could enable the quantitative characterization of damage during sliding along analog fault surfaces
Summary
Faults in the Earth’s crust are complex systems along which earthquakes nucleate and propagate [e.g., Wibberley et al (2008)]. For more mature faults having accumulated enough displacement, and above a given length scale [Candela and Brodsky (2016)], the topography of the fault planes is marked by slip induced wear, with striations and grooves of various wavelengths and amplitudes oriented along the main direction of slip [Engelder (1974); Edwards et al (2018)] If such morphological anisotropy of fault surfaces is well-known, its effect on the anisotropy of the frictional properties remains to be characterized. We study how the morphology of faults controls the static coefficient of friction and the anisotropy of friction with regards to the main stress orientation during slip To reach this goal, we produce 3D-prints of actual faults surfaces whose topography was measured in the field [Candela and Renard (2012)].
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