Frictional melting of gabbro under extreme experimental conditions of normal stress, acceleration, and sliding velocity
Publication date
2011
Authors
Niemeijer, A.
Di Toro, G.
Nielsen, S.
Di Felice, F.
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(c) UU Universiteit Utrecht, 2011
Abstract
With the advent of high‐velocity shear apparatus, several experimental studies have
been performed in recent years, improving our understanding of the evolution of fault
strength during seismic slip. However, these experiments were conducted under relatively
low normal stress (<20 MPa) and using small cylindrical samples where a large gradient in
slip velocity exists across the sliding surface. Given the above limitations, the extrapolation
of these experimental results to natural conditions is not trivial. Here we present results
from an experimental study on gabbroic rocks using a newly developed rotary shear
apparatus capable of reaching higher normal stress (up to 50 MPa) on ring‐shaped samples
(30/50 mm internal/external diameter) and allowing precise control of the imposed slip
velocity function. The results confirm that steady state shear stress during the melt‐lubricated
phase of the experiment depends on normal stress in the form of a power law equation as
predicted by theoretical models. However, the exponent appears closer to 0.5, contrary to the
theoretical prediction of 0.25. We observe no systematic dependence of shear stress on
acceleration, but increasing deceleration drastically decreases the recovery of friction during
final slip. We find that the slip‐weakening distance decreases inversely with increasing
normal stress, in agreement with theoretical considerations, and decreases with increasing
slip rate. Extrapolation of the slip‐weakening distance to natural conditions predicts a slip
velocity for ancient seismic events of 0.3–1 m/s when compared with field estimates. These
values compare well with seismological estimates.