High-Resolution Seismic Velocities and Shallow Structure of the San Andreas Fault Zone at Middle Mountain, Parkfield, California

doi:10.1785/0120010263

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High-Resolution Seismic Velocities and Shallow Structure of the San Andreas Fault Zone at Middle Mountain, Parkfield, California

R. D. Catchings, M. J. Rymer, M. R. Goldman, J. A. Hole, R. Huggins and C. Lippus

U.S. Geological Survey
345 Middlefield Rd.
MS 977
Menlo Park, California 94587
catching{at}usgs.gov
(R.D.C., M.J.R., M.R.G.)

Department of Geological Sciences
4044 Derring Hall
Virginia Tech
Blacksburg, Virginia 24061-0420
(J.A.H.)

Geometrics, Inc.
2190 Fortune Drive
San Jose, California 95131
(R.H., C.L.)

A 5-km-long, high-resolution seismic imaging survey across theSan Andreas fault (SAF) zone and the proposed San Andreas FaultObservatory at Depth (SAFOD) drill site near Parkfield, California,shows that velocities vary both laterally and vertically. Velocitiesrange from <1.0 km/sec near the surface to as much as 4.8km/sec at 750-m depth. The lowest velocities (<1.0 to $~$ 3.0km/sec) correspond to unconsolidated sediment, mudstone, andsandstone in the near surface, and the higher velocities (>4.0km/sec) probably correspond to granitic rock of the Salinianblock, which is exposed a few kilometers southwest of the SAF.The depth to the top of probable granitic rock varies laterallyalong the seismic profile but is about 600 m below the surfaceat the proposed SAFOD site. We observe a prominent, lateral low-velocityzone (LVZ) beneath and southwest of the surface trace of theSAF. The LVZ is about 1.5 km wide at 300-m depth but tapersto about 600 m wide at 750-m depth. At the maximum depth ofthe velocity model (750 m), the LVZ is centered approximately400 m southwest of the surface trace of the SAF. Similar velocitiesand velocity gradients are observed at comparable depths on bothsides of the LVZ, suggesting that the LVZ is anomalous relativeto rocks on either side of it. Velocities within the LVZ arelower than those of San Andreas fault gouge, and the LVZ isalso anomalous with respect to gravity, magnetic, and resistivitymeasurements. Because of its proximity to the surface traceof the SAF, it is tempting to suggest that the LVZ representsa zone of fractured crystalline rocks at depth. However, theLVZ instead probably represents a tectonic sliver of sedimentaryrock that now rests adjacent to or encompasses the SAF. Sucha sliver of sedimentary rock implies fault strands on both sidesand possibly within the sliver, suggesting a zone of fault strandsat least 1.5 km wide at a depth of 300 m, tapering to about 600m wide at 750-m depth. Fluids within the sedimentary sliverare probably responsible for observed low-resistivity values.

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