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PSUsing Petroleum Industry 3D Surveys to Improve Understanding of Active Faults: The Palos Verdes Fault in San Pedro Bay, California*
By
Andrew W. Rigor1, Mark R. Legg2, Robert J. Mellors1, and Robert D. Francis3
Search and Discovery Article #40088 (2003)
*Adapted for online presentation from award-winning poster at Student Expo, Norman, OK, March, 2003.
1San Diego State University ([email protected])
2Legg Geophysical
1California State University Long Beach
Abstract
Large earthquakes on the Palos Verdes fault may be destructive to the nearby urban areas of the densely populated Los Angeles Basin. We interpret an industry 3D seismic survey (244 km2, CDP spacing 24.6 m inline, 50.3 m cross-line), and process and interpret three intersecting shallow 2D profiles (16 channel, 0.95 s depth, 3.125 m CDP spacing), to map the shallow geometry (<3.0 s two-way travel time) of the fault zone in San Pedro Bay. Several reflectors, tied to known stratigraphic boundaries using well logs, provide timing of interpreted features that are used to improve understanding of the fault activity and associated seismic hazard.
We observe five distinct fault segments in the area of the 3D survey. Each segment consists of one primary strand that is near vertical to at least 3.0 s two-way travel time, and one to five secondary strands forming a zone that varies from 700-2400 m width. Several of these fault strands break latest Quaternary sediment and are associated with bathymetrically observed deformation at the surface. Deformation character at fault bends is consistent with a right-slip dominated fault zone. Seismic reflections of growth and no-growth sequences above anticlines to the west of the fault and in the Quaternary deposits of the Wilmington graben to the east of the fault are imaged in the 2D surveys. These alternating styles in vertical deformation may be associated with lateral movement of sedimentary sequences along bends in the main fault strand.
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(Complete captions accompany full-size images and follow text.)
Click here to view sequence of Figure4(a), (b), and (c).
Click here to view sequence of Figure 6(a), (b), (c), (d), and (e).
3D Seismic Reflection Data (Figure 2)
2D Seismic Reflection Data (Figure 3)
The Palos Verdes fault zone has a general northwest trend (Figures 1 and 2). Bends in the fault are associated with bathymetric changes; similarly, there are topographic changes along the Newport-Inglewood and Whittier faults, the other two major right-slip faults of the Los Angeles Basin.. The fault zone with its pop-up structure includes multiple fault strands. It separates the study area into two distinct seismic characters--Palos Verde anticlinorium to the west and Wilmington “graben” to the east (Figures 1, 2, and 3). Time slices reveal a releasing bend in the southern part of the study area and a restraining bend in the center of the study area (Figures 4 and 5). The fault trend is near vertical to at least 3 s. Anticlines
within the study area are the San Pedro Bay anticlinorium and the “
The narrow, tilted wedge of Quaternary strata southwest of the fault is generally too shallow to be effectively imaged with the 3D data. However, lines from 2D seismic data show the approximate location of the Quaternary wedge of sediments overlying the Palos Verdes Hills and San Pedro Bay anticlinoria, the Palos Verdes fault zone, and the Wilmington “graben” (Figures 8 and 9). This growth wedge and the monocline east of the fault are variable along strike; they may reflect uplift that formed as sediments were translated into the restraining bend.
3D data provided by Chevron-Texaco. Research funded by Southern California Earthquake Center.
Figure 1. Index map. The box on the inset map shows the location of the Palos Verdes fault and study area. The polygon shows the area of the 3D seismic data. Lines in violet show the 2D seismic profile locations. Mapped faults are in red. Note changes in bathymetry associated with bends in the Palos Verde fault (PVFZ). Similarly, the topography changes along the Newport-Inglewood ((NIFZ) and Whittier (WF) faults, the other two major right-slip faults of the Los Angeles Basin (LA Basin).
Figure 2.
Chair-cut visualization of Figure 3. A fence diagram of the locations of three 2D lines on top of the 1436-1492 ms 3D time-slice. Green vertical lines show well locations with log data. Palos Verdes fault location is superimposed with the orange wireframe, and acoustic basement is shown as a surface when color changes with depth.
Figure
4(a-c).
Figure 5.
The location of the segments and features of the Palos Verdes fault
through the
Figure
6(a-e). Individual cross-sections through segments A through E are
labeled A-A’ through E-E’ and shown with interpreted faults and
horizons. Anticlines within this survey are the San Pedro Bay anticlinorium (SPBA) and the “ Figure 7. A broad anticline, perpendicular to the fault, below Pliocene horizon “C-2,” with associated growth through “C-top,” may be an indicator of initiation of right-slip motion along the fault zone. Color indicates depth to horizon “C-2.” Figure 8(a-b). Close-ups of 300 ms of 2D data from (a) line 80a, above, and (b) 81, below, have been annotated to show approximate location of the Quaternary wedge of sediments overlying the Palos Verdes Hills and San Pedro Bay anticlinoria (unconformity in green), the Palos Verdes fault zone (PVF), and the Wilmington “graben.” The narrow tilted wedge of Quaternary strata lying to the southwest of the fault is generally too shallow to be effectively imaged with the 3D data; note line 80a roughly corresponds to cross-section D-D’ (Figure 6(d)). This growth wedge and the monocline to the east of the fault appear variable along strike and may be due to uplift created as sediments have been recently translated into the restraining bend. Figure 9. 2-D, E-W seismic line 81 that extends across and beyond the study area. The Palos Verdes fault zone (PVF) is characterized by change in character across it, as well as the development of the Quaternary wedge highlighted in Figure 8(b).
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