close-up of the fault interface, as viewed through the slider block from a high angle.

A close-up of the fault interface, as viewed through the slider block from a high angle. The white patches are the bottom surface of the asperities. These were created by laser cuts into the slider block exterior, which rests against the base plate, below. (Photos by Adam Lau)

At fault

Jess Parker perfoming experiment on aperities in the labParker applies different forces to a fault interface, made of an acrylic slider block and a base plate. When all or part of the fault can no longer hold up, it causes slippage — comparable to a mini-earthquake. Using acoustic emission sensors as seismometers, the researchers can measure which asperities fail, and when, in a highly detailed way.A seismic rupture often occurs over a single asperity, an uneven area on a fault where friction causes it to be stuck. When an asperity slips, it produces seismic waves that can trigger additional movement along the fault, resulting in another earthquake. Civil and environmental engineering Ph.D. student Jes Parker, working in the lab of professor Steven Glaser, is part of a team that is taking research on asperities to a new level, studying fault mechanics at the nanoscale. “As far we can tell, friction behaves the same at all scales,” Parker said. “So the energy signature of events in the lab can show a miniature version of full-scale tectonic earthquakes.”


Topics: Civil engineering, Nanotechnology, Research


Reach the editors at berkeleyengineer@berkeley.edu