A number of observations indicate that an upper stability transition occurs along well‐developed faults, such as the San Andreas, as a result of unconsolidated gouge within shallow regions of these faults. These observations include the depth distribution of seismicity along faults with and without well‐developed gouge zones, correlations between seismicity and shallow crustal structure, and modeling of coseismic and post‐seismic slip. In addition, recent experimental friction studies indicate that thick layers of simulated gouge exhibit a positive slip‐rate dependence of frictional resistance (velocity strengthening) and thus inherently stable slip, whereas bare rock surfaces and thin gouge layers exhibit potentially unstable velocity weakening behavior. Subduction zones with large accretionary wedges also exhibit an upper stability transition in that slip is aseismic within the accretionary wedge. A stability transition due to the presence of unconsolidated material can also be invoked in this case. Copyright 1988 by the American Geophysical Union.
The depth of seismic faulting and the upper transition from stable to unstable slip regimes / Marone, C. J.; Scholz, C. H.. - In: GEOPHYSICAL RESEARCH LETTERS. - ISSN 0094-8276. - 15:6(1988), pp. 621-624. [10.1029/GL015i006p00621]
The depth of seismic faulting and the upper transition from stable to unstable slip regimes
Marone C. J.
Membro del Collaboration Group
;
1988
Abstract
A number of observations indicate that an upper stability transition occurs along well‐developed faults, such as the San Andreas, as a result of unconsolidated gouge within shallow regions of these faults. These observations include the depth distribution of seismicity along faults with and without well‐developed gouge zones, correlations between seismicity and shallow crustal structure, and modeling of coseismic and post‐seismic slip. In addition, recent experimental friction studies indicate that thick layers of simulated gouge exhibit a positive slip‐rate dependence of frictional resistance (velocity strengthening) and thus inherently stable slip, whereas bare rock surfaces and thin gouge layers exhibit potentially unstable velocity weakening behavior. Subduction zones with large accretionary wedges also exhibit an upper stability transition in that slip is aseismic within the accretionary wedge. A stability transition due to the presence of unconsolidated material can also be invoked in this case. Copyright 1988 by the American Geophysical Union.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.