T41A-2869
Understanding strain transfer and basin evolution complexities in the Salton pull-apart basin near the Southern San Andreas Fault

Thursday, 17 December 2015
Poster Hall (Moscone South)
Annie M Kell1, Valerie J Sahakian2, Graham M Kent3, Neal W Driscoll4, Alistair J Harding2, Robert L Baskin5, Michael Barth6, John A Hole7, Joann M Stock8 and Gary S Fuis9, (1)University of Nevada Reno, Incline Village, NV, United States, (2)University of California San Diego, La Jolla, CA, United States, (3)University of Nevada Reno, Nevada Seismological Laboratory, Reno, NV, United States, (4)Scripps Institution of Oceanog, La Jolla, CA, United States, (5)USGS Salt Lake City, Utah, Salt Lake City, UT, United States, (6)Subsea Systems, Inc., Ventura, CA, United States, (7)Virginia Polytechnic Institute and State University, Blacksburg, VA, United States, (8)California Institute of Technology, Division of Geological and Planetary Sciences, Pasadena, CA, United States, (9)USGS California Water Science Center Menlo Park, Menlo Park, CA, United States
Abstract:
Active source seismic data in the Salton Sea provide insight into the complexity of the pull-apart system development. Seismic reflection data combined with tomographic cross sections give constraints on the timing of basin development and strain partitioning between the two dominant dextral faults in the region; the Imperial fault to the southwest and the Southern San Andreas fault (SSAF) to the northeast. Deformation associated with this step-over appears young, having formed in the last 20-40 k.a. The complexity seen in the Salton Sea is similar to that seen in pull-apart basins worldwide. In the southern basin of the Salton Sea, a zone of transpression is noted near the southern termination of the San Andreas fault, though this stress regime quickly transitions to a region of transtension in the northern reaches of the sea. The evolution seen in the basin architecture is likely related to a transition of the SSAF dying to the north, and giving way to youthful segments of the Brawley seismic zone and Imperial fault.

Stratigraphic signatures seen in seismic cross-sections also reveal a long-term component of slip to the southwest on a fault 1-2 km west of the northeastern Salton Sea shoreline. Numerous lines of evidence, including seismic reflection data, high-resolution bathymetry within the Salton Sea, and folding patterns in the Borrego Formation to the east of the sea support an assertion of a previously unmapped fault, the Salton Trough fault (STF), parallel to the SAF and just offshore within the Salton Sea. Seismic observations are seen consistently within two datasets of varying vertical resolutions, up to depths of 4-5 km, suggesting that this fault strand is much longer-lived than the evolution seen in the southern sub-basin.

The existence of the STF unifies discrepancies between the onshore seismic studies and data collected within the sea. The STF likely serves as the current bounding fault to the active pull-apart system, as it aligns with the “rung-and-ladder” seismicity seen within the Salton Sea. Additionally, the presence of the STF may explain the gaps seen in the paleoseismic record along the SSAF (i.e. Philibosian et al., 2011), which shows an extended period of non-rupture. The STF may play a role in strain release along the SSAF, so a combined history may yield improved insight to the long periods of quiescence.

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