Paglialunga, FedericaPasselègue, François Xavier ThibaultAcosta, MateoViolay, Marie2021-06-222021-06-222021-06-222021-06-2210.1029/2021GL093619https://infoscience.epfl.ch/handle/20.500.14299/179493Seismological observations highlighted that earthquakes are often followed by changes in elastic properties around the fault zone. Here, we studied the origin of these variations using stick-slip experiments on saw-cut granite samples presenting different degrees of bulk damage (i.e., microcracks). Stick-slip events were induced under triaxial compression configuration with continuous active ultrasonic measurements at confining pressures representative of upper crustal conditions (15–120 MPa). Both the P-wave velocity (urn:x-wiley:00948276:media:grl62539:grl62539-math-0001) and amplitude (urn:x-wiley:00948276:media:grl62539:grl62539-math-0002) showed drops, concurrently with stress drops, and had a non-monotonic dependence toward the fault's stress state. Our experimental results suggest that co-seismic changes in urn:x-wiley:00948276:media:grl62539:grl62539-math-0003 were mostly controlled by the elastic re-opening of microcracks in the bulk, rather than by co-seismic damage or the formation of fault gouge. Co-seismic changes in urn:x-wiley:00948276:media:grl62539:grl62539-math-0004 were controlled by a combination of elastic re-opening of microcracks in the bulk and inelastic processes (i.e., co-seismic damage and gouge formation and dilation).Damage zoneDynamic ruptureFaultingFrictionSeismic propertiestext::journal::journal article::research article