In the brittle regime, faults tend to be oriented along an angle of about 30 relative to the principal stress direction. This empirical Andersonian observation is usually explained by the orientation of the stress tensor and the slope of the yield envelope defined by the Mohr-Coulomb criterion, often called critical-stress theory, assuming frictional properties of the crustal rocks (friction coefficient = 0.6-0.8). However, why the slope has a given value? We suggest that the slope dip is constrained by the occurrence of the largest shear stress gradient along that inclination. High homogeneous shear stress, i.e., without gradients, may generate aseismic creep as for example in flat decollements, both along thrusts and low angle normal faul...
Analysis of seismicity can illuminate active fault zone structures but also deformation within large...
Although large, low-angle normal faults in the continental crust are widely recognized, doubts persi...
Low angle normal faults and other weak faults are common in the metamorphic core of collisional orog...
Crustal scale fault zones extend below the brittle-ductile transition as ductile shear zones. Here w...
International audienceOrientations of natural fault systems are subject to large variations. They of...
Crustal scale fault zones extend below the brittle-ductile transition as ductile shear zones. Here w...
In this paper, we model the crack growth in an elastic medium constituted by two welded half-spaces ...
Fault surfaces are typically non-planar and display either groove-like relief features parallel to ...
We investigate the mechanical properties of the oceanic lithosphere using earthquake focal mechanism...
It has been assumed that the orientation of the maximum horizontal compressive stress (SHmax) in the...
International audienceThe reactivation of faults with near-optimal orientations is commonly consider...
We propose that the brittle-ductile transition (BDT) controls the seismic cycle. In particular, the ...
The major bends of the San Andreas fault in California are associated with significant variations in...
Shallow dip angles (⩽45°) suggested by field observations of continental extensional faults are not ...
Analysis of seismicity can illuminate active fault zone structures but also deformation within large...
Although large, low-angle normal faults in the continental crust are widely recognized, doubts persi...
Low angle normal faults and other weak faults are common in the metamorphic core of collisional orog...
Crustal scale fault zones extend below the brittle-ductile transition as ductile shear zones. Here w...
International audienceOrientations of natural fault systems are subject to large variations. They of...
Crustal scale fault zones extend below the brittle-ductile transition as ductile shear zones. Here w...
In this paper, we model the crack growth in an elastic medium constituted by two welded half-spaces ...
Fault surfaces are typically non-planar and display either groove-like relief features parallel to ...
We investigate the mechanical properties of the oceanic lithosphere using earthquake focal mechanism...
It has been assumed that the orientation of the maximum horizontal compressive stress (SHmax) in the...
International audienceThe reactivation of faults with near-optimal orientations is commonly consider...
We propose that the brittle-ductile transition (BDT) controls the seismic cycle. In particular, the ...
The major bends of the San Andreas fault in California are associated with significant variations in...
Shallow dip angles (⩽45°) suggested by field observations of continental extensional faults are not ...
Analysis of seismicity can illuminate active fault zone structures but also deformation within large...
Although large, low-angle normal faults in the continental crust are widely recognized, doubts persi...
Low angle normal faults and other weak faults are common in the metamorphic core of collisional orog...