2007
DOI: 10.1029/2006jb004465
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Seismically active wedge structure beneath the Coalinga anticline, San Joaquin basin, California

Abstract: [1] We define the subsurface geometry, kinematics, and seismotectonics of the Coalinga anticline in the San Joaquin basin, central California. Using seismic reflection data and quantitative fault-related folding techniques, we present a model of the Coalinga anticline that demonstrates that the structure is composed of a stack of imbricated structural wedges, related to two major fault ramps at depth, the deepest of which ruptured during the 1983 Coalinga (M w = 6.5) earthquake. Because of the lack of basinwar… Show more

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Cited by 39 publications
(29 citation statements)
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“…The 1983 M W 6.5 Coalinga earthquake, for instance, had maximum surface uplift of 0.5 m from a combined rupture length of 20-35 km with primary and secondary slip on several shallow (<30°) ramp thrusts and bedding-plane reverse faults above a 10 km main shock depth (Eaton, 1990;Stein and Ekström, 1992). However, the maximum surface uplift was not on a fault scarp but occurred directly above an actively growing fault-bend fold at depth, where no beddingplane reverse faults were observed at the surface (Guzofski et al, 2007).…”
Section: The Late Holocene Toe Jam Hill/point Glover Bedding-plane Rementioning
confidence: 94%
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“…The 1983 M W 6.5 Coalinga earthquake, for instance, had maximum surface uplift of 0.5 m from a combined rupture length of 20-35 km with primary and secondary slip on several shallow (<30°) ramp thrusts and bedding-plane reverse faults above a 10 km main shock depth (Eaton, 1990;Stein and Ekström, 1992). However, the maximum surface uplift was not on a fault scarp but occurred directly above an actively growing fault-bend fold at depth, where no beddingplane reverse faults were observed at the surface (Guzofski et al, 2007).…”
Section: The Late Holocene Toe Jam Hill/point Glover Bedding-plane Rementioning
confidence: 94%
“…Bedding-plane faults have ruptured coseismically and produced surface scarps in conjunction with large earthquakes on deeper structures (Lensen and Otway, 1971;Philip and Meghraoui, 1983;Hull, 1990;Treiman, 1995;Yeats, 2000). While in some cases bedding-plane faults above thrust wedges and passive roof duplexes root in thrust ramps or roof thrusts (Banks and Warburton, 1986;Guzofski et al, 2007), in other cases bedding-plane reverse faults root in the axial plane region of folds (Shaw and Suppe, 1994;Ishiyama et al, 2004).…”
Section: Can Bedding-plane Faults Generate Earthquakes?mentioning
confidence: 97%
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“…Buried or blind faults that have the potential to rupture as large earthquakes make the construction of reliable seismic hazard and risk maps extremely difficult in numerous regions worldwide (Ambraseys, 1981;Calais et al, 2010;Dolan et al, 2003;Feng et al, 2010;Guzofski et al, 2007;Jackson, 2006;Leon et al, 2009;Lettis et al, 1997;MonaLisa et al, 2007;Shyu et al, 2005;Talebian et al, 2004). Since ruptures on such faults may cause dislocation or folding of the overlying strata, their presence at some locations may be deduced from detailed geomorphological studies and/or paleoseismological and geophysical investigations of the shallow sedimentary units.…”
Section: Introductionmentioning
confidence: 96%