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all geography including DSDP/ODP Sites and Legs
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San Timoteo Badlands
Magnetostratigraphy and biochronology of the San Timoteo Badlands, southern California, with implications for local Pliocene–Pleistocene tectonic and depositional patterns
Spatial and Temporal Deformation along the Northern San Jacinto Fault, Southern California: Implications for Slip Rates
A variety of extensional and contractional structures is produced by strike slip faulting. The variety and extent of the structures are directly related to the kind and extent of geometric complexities of the fault zone or system. The area of convergence of the San Andreas fault zone and the much younger San Jacinto fault zone in the eastern Transverse Ranges is exquisitely complex. We propose that the San Jacinto fault zone formed in response to a structural knot in San Gorgonio Pass probably within the past 1.5 Ma. In the area of their convergence we propose that slip is transferred both east and west from the San Jacinto fault zone northward to the San Andreas fault zone over a 60-to 70-km band that extends northwestward from the south end of the San Bernardino basin to the east end of the San Gabriel Mountains. We further propose several structural adjustments as a consequence of onset or acceleration of lateral movement on the San Jacinto fault zone: accelerated uplift of the eastern San Gabriel Mountains, development or accentuation of an arcuate schuppen-like structure in the eastern San Gabriel Mountains, inception of the San Bernardino basin, cessation of deposition in the present-day San Timoteo badlands area, inception of the San Jacinto basin, and an increase in compression and uplift in the San Gorgonio Pass area. We interpret the uplift and compression in San Gorgonio Pass to result from two formerly disparate structural blocks—the eastern San Bernardino and San Jacinto blocks—becoming a relatively coherent block, and the San Gorgonio Pass area constituting a left step between the San Andreas fault zone in the Coachella Valley area and the San Jacinto fault zone in the San Jacinto Valley area. The compression and uplift led to the formation of the San Gorgonio Pass thrust faults and disruption of any through-going San Andreas strands, at least at the surface. In partitioning slip between the San Andreas and San Jacinto fault zones, consideration should be given to the bandwidth over which horizontal strain has accumulated. The average slip rate of the northern part of the San Jacinto fault zone during the past 1.5 m.y. may have been about 20 mm/yr and about 15 mm/yr on the San Andreas. South of the San Bernardino basin, current strain accumulation based on repeated geodetic surveys is nearly equally divided between the San Jacinto and San Andreas fault zones.