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Journal Article

Oak Ridge fault, Ventura fold belt, and the Sisar decollement, Ventura basin, California

Robert S. Yeats, Gary J. Huftile, F. Bryan Grigsby
Journal: Geology
Published: 01 December 1988
Geology (1988) 16 (12): 1112–1116.
DOI: https://doi.org/10.1130/0091-7613(1988)016<1112:ORFVFB>2.3.CO;2
..., borehole breakouts, and piercing-point offset of the South Mountain seaknoll by the Oak Ridge fault. A northeast-trending line connecting the west end of Oak Ridge and the east end of the Sisar fault separates an eastern domain where late Quaternary displacement is taken up entirely on the Oak Ridge fault...
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Book Chapter

OAK RIDGE FAULT, VENTURA FOLD BELT, AND THE SISAR DECOLLEMENT, VENTURA BASIN, CALIFORNIA

Author(s)
Robert S. Yeats, Gary J. Huftile, F. Bryan Grigsby
...-point offset of the South Mountain seaknoll by the Oak Ridge fault. A NE-trending line connecting the west end of Oak Ridge and the east end of the Sisar fault separates an eastern domain where late Quaternary displacement is taken up entirely on the Oak Ridge fault and a western domain where...
FIGURES
Abstract
View PDF for content titled, OAK RIDGE <span class="search-highlight">FAULT</span>, VENTURA FOLD BELT, AND THE <span class="search-highlight">SISAR</span> DECOLLEMENT, VENTURA BASIN, CALIFORNIA
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ABSTRACT The rootless Ventura Avenue, San Miguelito, and Rincon anticlines (Ventura fold belt) in Pliocene-Pleistocene turbidites are related to south-dipping reverse faults rising from a decollement in underlying Miocene shale. To the east, Sulphur Mountain anticlinorium comprises the upper plate of a south-dipping set of thrusts (Sisar, Big Canyon, Lion) that merge downward into a decollement in mudstone of the Rincon Formation, named here the Sisar decollement. Shortening of the Miocene and younger sequence is ~3 km greater than that of the underlying competent Vaqueros, Sespe, and marine Eocene sequence in the Ventura fold belt and ~7 km greater farther east at Sulphur Mountain. Cross section balancing requires that this difference be taken up by the Paleogene sequence at the Oak Ridge fault to the south. Convergence is NE to NNE based on earthquake focal mechanisms and piercing-point offset of the South Mountain seaknoll by the Oak Ridge fault. A NE-trending line connecting the west end of Oak Ridge and the east end of the Sisar fault separates an eastern domain where late Quaternary displacement is taken up entirely on the Oak Ridge fault and a western domain where displacement is transferred to the Sisar decollement and its overlying rootless folds. This implies that (1) the Oak Ridge fault near the coast presents as much seismic risk as it does farther east, despite negligible shallow post-0.2 Ma movement, (2) ground-rupture hazard is high for the Sisar fault set in the upper Ojai Valley, and (3) the decollement could fail on a low-angle thrust at depth and produce an earthquake analogous to the 1987 Whittier Narrows event in Los Angeles.

Image
—Structure-contour map on the main and north strands of the San Cayetano fault, and the upper and lower Sisar faults. Contours on the upper Sisar fault and the north strand of the San Cayetano fault are shown in heavy lines. Contour interval is 1000 ft (305 m). Contours are shown only where controlled by well data.

—Structure-contour map on the main and north strands of the San Cayetano fa...

Published: 01 August 1991
Figure 9 —Structure-contour map on the main and north strands of the San Cayetano fault, and the upper and lower Sisar faults. Contours on the upper Sisar fault and the north strand of the San Cayetano fault are shown in heavy lines. Contour interval is 1000 ft (305 m). Contours are shown only
Journal Article

Geology of North Sulphur Mountain Field, Ventura County: ABSTRACT

I. T. Schwade, Spencer Fine
Journal: AAPG Bulletin
Published: 01 December 1949
AAPG Bulletin (1949) 33 (12): 2061.
DOI: https://doi.org/10.1306/3D933E60-16B1-11D7-8645000102C1865D
... feet. Both wells passed through a thrust fault from Pliocene into Miocene; however, as located, well No. 44 encountered only a small amount of lower Mohnian and was completed largely in older beds. The rediscovery of the field came about in 1947 with the drilling of No. 45 for the purpose...
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Journal Article

Thin-Skinned Tectonics of the Upper Ojai Valley and Sulphur Mountain Area, Ventura Basin, California

Gary J. Huftile
Journal: AAPG Bulletin
Published: 01 August 1991
AAPG Bulletin (1991) 75 (8): 1353–1373.
DOI: https://doi.org/10.1306/0C9B294D-1710-11D7-8645000102C1865D
...Figure 9 —Structure-contour map on the main and north strands of the San Cayetano fault, and the upper and lower Sisar faults. Contours on the upper Sisar fault and the north strand of the San Cayetano fault are shown in heavy lines. Contour interval is 1000 ft (305 m). Contours are shown only...
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View PDF for article title, Thin-Skinned Tectonics of the Upper Ojai Valley and Sulphur Mountain Area, Ventura Basin, California
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Image
—Subcrop geologic map showing Lion Mountain anticline, Reeves syncline. This map is a subcrop map beneath younger, unfolded features including the San Cayetano fault, Saugus Formation, Lion fault, and alluvial-fan deposits as illustrated in cross section XX’. Note the change in structural response to folding between the Vaqueros and Rincon Formations, viewing downplunge on the Lion Mountain anticline. (b) Subcrop geologic map showing the south flank of the Big Canyon syncline beneath the Sisar fault and at the surface as illustrated in cross section YY’. To the left is the unnamed syncline that produces in the Sulphur Mountain area of the Ojai oil field (Figure 5a). The Miocene Monterey Formation is shaded. See Figure 2 for formation abbreviations.

—Subcrop geologic map showing Lion Mountain anticline, Reeves syncline. Thi...

Published: 01 August 1991
in structural response to folding between the Vaqueros and Rincon Formations, viewing downplunge on the Lion Mountain anticline. (b) Subcrop geologic map showing the south flank of the Big Canyon syncline beneath the Sisar fault and at the surface as illustrated in cross section YY’. To the left is the unnamed
Image
Map view of the three-dimensional fault surfaces used in the topology model (a) and the planar model (b) of this study. Surfaces are defined in the SCECCFM version 2.5, and steep-dipping, major faults are extended to 27.5 km. Faults not extended to 27.5 km include (1) the Simi–Santa Rosa fault, which is modeled as a back thrust off of the Oak Ridge fault (Huftile and Yeats, 1996), (2) the Holser and Del Valle faults, which are truncated at their lower tips by the Santa Susana fault, (3) Mission Ridge–Arroyo Parida fault, which is truncated at its lower tip by the Red Mountain fault (Huftile and Yeats, 1995), (4) the Sisar fault, a flexural slip fault (Yeats, 1988a), which is modeled as a listric fault, and (5) offshore faults, which are not extended with the exception of the Oak Ridge and Red Mountain faults. Planar surfaces are created by calculating average strike and dip of fault surfaces in the topology model and creating a new semirectangular surface with an orientation and trace length similar to the corresponding CFM surface. Fault traces are highlighted with black lines and upper tiplines of blind faults are highlighted with dashed lines. Models are illuminated from the north with darker color indicating deeper depth. South-dipping faults are backlit to enhance differences in dip direction. A black line marks the coast. Projection is UTM (NAD1927). For a three-dimensional interactive version of this figure, refer to the electronic supplement to this article.

Map view of the three-dimensional fault surfaces used in the topology model...

Published: 01 June 2008
fault ( Huftile and Yeats, 1995 ), (4) the Sisar fault, a flexural slip fault ( Yeats, 1988a ), which is modeled as a listric fault, and (5) offshore faults, which are not extended with the exception of the Oak Ridge and Red Mountain faults. Planar surfaces are created by calculating average strike
Image
Map view of the three-dimensional fault surfaces used in the topology model (a) and the planar model (b) of this study. Surfaces are defined in the SCECCFM version 2.5, and steep-dipping, major faults are extended to 27.5 km. Faults not extended to 27.5 km include (1) the Simi–Santa Rosa fault, which is modeled as a back thrust off of the Oak Ridge fault (Huftile and Yeats, 1996), (2) the Holser and Del Valle faults, which are truncated at their lower tips by the Santa Susana fault, (3) Mission Ridge–Arroyo Parida fault, which is truncated at its lower tip by the Red Mountain fault (Huftile and Yeats, 1995), (4) the Sisar fault, a flexural slip fault (Yeats, 1988a), which is modeled as a listric fault, and (5) offshore faults, which are not extended with the exception of the Oak Ridge and Red Mountain faults. Planar surfaces are created by calculating average strike and dip of fault surfaces in the topology model and creating a new semirectangular surface with an orientation and trace length similar to the corresponding CFM surface. Fault traces are highlighted with black lines and upper tiplines of blind faults are highlighted with dashed lines. Models are illuminated from the north with darker color indicating deeper depth. South-dipping faults are backlit to enhance differences in dip direction. A black line marks the coast. Projection is UTM (NAD1927). For a three-dimensional interactive version of this figure, refer to the electronic supplement to this article.

Map view of the three-dimensional fault surfaces used in the topology model...

Published: 01 June 2008
fault ( Huftile and Yeats, 1995 ), (4) the Sisar fault, a flexural slip fault ( Yeats, 1988a ), which is modeled as a listric fault, and (5) offshore faults, which are not extended with the exception of the Oak Ridge and Red Mountain faults. Planar surfaces are created by calculating average strike
Image
—Schematic cross sections illustrating the development of Sulphur Mountain anticlinorium. No vertical exaggeration. See Figure 2 for formation abbreviations. Dotted faults represent restored movement on faults. Tfp, Pico member of the Fernando Formation; Tfr, Repetto member. (a) Middle to late Pleistocene. Sulphur Mountain anticlinorium is rising as a fault-propagation fold with the fault tip of Big Canyon fault (BCF) in the hinge of the Big Canyon syncline (BCS). (b) Late Pleistocene. Movement on the Big Canyon, Upper Sisar (SF), and South Sulphur Mountain (SSMF) faults. (c) Represents present structure including that shown in Figure 5b following movement on the Lower Sisar (LSF) and Lion (LF) faults.

—Schematic cross sections illustrating the development of Sulphur Mountain ...

Published: 01 August 1991
. (a) Middle to late Pleistocene. Sulphur Mountain anticlinorium is rising as a fault-propagation fold with the fault tip of Big Canyon fault (BCF) in the hinge of the Big Canyon syncline (BCS). (b) Late Pleistocene. Movement on the Big Canyon, Upper Sisar (SF), and South Sulphur Mountain (SSMF) faults. (c
Image
Schematic north–south cross sections showing alternate models for the Ventura Avenue anticline and Ventura fault. (a) Cross section after Yeats (1982a) and Huftile and Yeats (1995). In this model, the Ventura Avenue anticline is a north‐vergent detachment fold lifting off of the Sisar decollement; minor faulting in the interior of the anticline is constrained by well data. The Ventura fault is a minor bending‐moment fault in the syncline at the southern edge of the anticline. (b) Our interpretation, modeled in part after Sarna‐Wojcicki and Yerkes (1982). The Ventura Avenue anticline is produced as a consequence of shortening on the Ventura fault, which is a steeply dipping south‐vergent thrust fault rising from the Sisar decollement. Slip on the blind ramp to the north is partitioned between the Lion backthrust and the Ventura fault. The color version of this figure is available only in the electronic edition.

Schematic north–south cross sections showing alternate models for the Ventu...

Published: 06 May 2014
of the Sisar decollement; minor faulting in the interior of the anticline is constrained by well data. The Ventura fault is a minor bending‐moment fault in the syncline at the southern edge of the anticline. (b) Our interpretation, modeled in part after Sarna‐Wojcicki and Yerkes (1982) . The Ventura Avenue
Journal Article

Structure and Seismic Hazard of the Ventura Avenue Anticline and Ventura Fault, California: Prospect for Large, Multisegment Ruptures in the Western Transverse Ranges

Judith Hubbard, John H. Shaw, James Dolan, Thomas L. Pratt, Lee McAuliffe, Thomas K. Rockwell
Published: 06 May 2014
Bulletin of the Seismological Society of America (2014) 104 (3): 1070–1087.
DOI: https://doi.org/10.1785/0120130125
... of the Sisar decollement; minor faulting in the interior of the anticline is constrained by well data. The Ventura fault is a minor bending‐moment fault in the syncline at the southern edge of the anticline. (b) Our interpretation, modeled in part after Sarna‐Wojcicki and Yerkes (1982) . The Ventura Avenue...
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View PDF for article title, Structure and Seismic Hazard of the Ventura Avenue Anticline and Ventura <span class="search-highlight">Fault</span>, California: Prospect for Large, Multisegment Ruptures in the Western Transverse Ranges
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Journal Article

Neotectonics of the San Cayetano fault, Transverse Ranges, California

THOMAS ROCKWELL
Journal: GSA Bulletin
Published: 01 April 1988
GSA Bulletin (1988) 100 (4): 500–513.
DOI: https://doi.org/10.1130/0016-7606(1988)100<0500:NOTSCF>2.3.CO;2
...THOMAS ROCKWELL Abstract Study of late Quaternary alluvial deposits cut by the San Cayetano reverse fault indicates that the dip-slip rate of faulting increases from 1.05 ± 0.2 mm/yr at Sisar Creek near the western end of the fault eastward to 1.35 ± 0.4 mm/ yr at Bear Canyon and 2.35 ± 0.55...
View PDF for article title, Neotectonics of the San Cayetano <span class="search-highlight">fault</span>, Transverse Ranges, California
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Image
The tectonic setting of the Western Transverse Ranges with faults from the Southern California Community Fault Model (Plesch et al., 2007; Nicholson et al., 2017). Thin white lines are rivers. Focal mechanism solution is for the Mw 6.7 1994 Northridge earthquake (Huftile and Yeats, 1996). The line A-A′ refers to cross section in Figure S1 (see footnote 1). SCRV—Santa Clara River valley; WSCF—western section of the San Cayetano fault; ESCF—eastern section of the San Cayetano fault; SSCF—Southern San Cayetano fault; LA—Los Angeles; LFS—Lion fault set (Sisar, Big Canyon, and Lion Canyon faults); APF—Arroyo-Parida fault; SAF—San Andreas fault.

The tectonic setting of the Western Transverse Ranges with faults from the ...

Published: 05 January 2022
, 1996 ). The line A-A′ refers to cross section in Figure S1 (see footnote 1 ). SCRV—Santa Clara River valley; WSCF—western section of the San Cayetano fault; ESCF—eastern section of the San Cayetano fault; SSCF—Southern San Cayetano fault; LA—Los Angeles; LFS—Lion fault set (Sisar, Big Canyon, and Lion
Image
Schematic illustration showing how the slip vectors change in a ramp–flat–ramp fault geometry. Dashed lines show active fold axes (across which the slip vectors change) and inactive fold axes (which have been passively transported from the fault bends). Reference level A marks the original, undeformed bedding geometry. In this case, the magnitude of slip on the deep ramp is ∼1.6 times that on the detachment, because slip is consumed by folding across the fault bend. In contrast, slip is neither consumed nor generated at the second fault bend because this is a special case in which the beds are parallel to the detachment and therefore parallel to the upper ramp. The geometry shown here is simpler than the Sisar–Ventura case because the lower ramp merges directly onto the detachment rather than via multiple bends. See pages 17–18 of Shaw et al. (2005) for details. The color version of this figure is available only in the electronic edition.

Schematic illustration showing how the slip vectors change in a ramp–flat–r...

Published: 06 May 2014
Figure 13. Schematic illustration showing how the slip vectors change in a ramp–flat–ramp fault geometry. Dashed lines show active fold axes (across which the slip vectors change) and inactive fold axes (which have been passively transported from the fault bends). Reference level A marks
Journal Article

Structural modeling of the Western Transverse Ranges: An imbricated thrust ramp architecture

Y. Levy, T.K. Rockwell, J.H. Shaw, A. Plesch, N.W. Driscoll, H. Perea
Journal: Lithosphere
Publisher: GSW
Published: 04 November 2019
Lithosphere (2019) 11 (6): 868–883.
DOI: https://doi.org/10.1130/L1124.1
... interpretations for this region ( Fig. 5 ). Yeats et al. (1988) presented balanced cross sections with a dominant north-verging structure, the Sisar décollement, at 8 km depth, south of the Red Mountain and San Cayetano faults. In their model ( Fig. 5A ), both the Ventura Avenue anticline and the Sulphur...
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Journal Article

Structural Trend Analysis by Axial Surface Mapping: Discussion

Donald S. Stone
Journal: AAPG Bulletin
Published: 01 May 1996
AAPG Bulletin (1996) 80 (5): 770–779.
DOI: https://doi.org/10.1306/64ED88B8-1724-11D7-8645000102C1865D
... fault, Ventura fold belt, and the Sisar decollement, Ventura basin, California : Geology , v. 16 , p. 1112 – 1116 . Yerkes , R. F. , A. M. Sarn-Wojcicki , and K. R. Lajoie , 1987 , Geology and Quaternary deformation of the Ventura area : U.S. Geological Survey Professional...
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Book Chapter

ROAD LOG

Book: DEPOSITIONAL ENVIRONMENTS, STRUCTURE, AND TECTONICS OF THE WESTERN TRANSVERSE RANGES, VENTURA COUNTY, CALIFORNIA
Series: Guidebook
Publisher: The Pacific Section American Association of Petroleum Geologist
Published: 01 January 1996
DOI: 10.32375/1996-CGSGB-DEP.3
EISBN: 9798990163911
... on the north and the south-dipping Sisar-Big Canyon-Lion fault set on the south. These south-dipping faults are late Quaternary in age; the San Cayetano fault is still active. Huftile (1991) reports movement on this fault near Sisar Creek at a rate of about 1 mm/yr. - - Lion Creek, which drains...
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Journal Article

Effects of Nonplanar Fault Topology and Mechanical Interaction on Fault-Slip Distributions in the Ventura Basin, California

Scott T. Marshall, Michele L. Cooke, Susan E. Owen
Published: 01 June 2008
Bulletin of the Seismological Society of America (2008) 98 (3): 1113–1127.
DOI: https://doi.org/10.1785/0120070159
... fault ( Huftile and Yeats, 1995 ), (4) the Sisar fault, a flexural slip fault ( Yeats, 1988a ), which is modeled as a listric fault, and (5) offshore faults, which are not extended with the exception of the Oak Ridge and Red Mountain faults. Planar surfaces are created by calculating average strike...
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View PDF for article title, Effects of Nonplanar <span class="search-highlight">Fault</span> Topology and Mechanical Interaction on <span class="search-highlight">Fault</span>-Slip Distributions in the Ventura Basin, California
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Journal Article

Alternate fault model for the Santa Barbara, California, earthquake of 13 August 1978

Robert S. Yeats, Daniel J. Olson
Published: 01 October 1984
Bulletin of the Seismological Society of America (1984) 74 (5): 1545–1553.
DOI: https://doi.org/10.1785/BSSA0740051545
... are locally prominent on the northern flank of the Ventura basin including the Sisar fault in the upper Ojai Valley (Schlueter, 1976) and faults related to flexural-slip folding (Keller et al., 1982). The western Transverse Ranges are characterized by seismically active north- dipping reverse faults which...
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Journal Article

Neotectonics of the Offshore Oak Ridge Fault near Ventura, Southern California

Michael A. Fisher, H. Gary Greene, William R. Normark, Ray W. Sliter
Published: 01 April 2005
Bulletin of the Seismological Society of America (2005) 95 (2): 739–744.
DOI: https://doi.org/10.1785/0120040126
... , R. S. , G. J. Huftile , and F. B. Grigsby ( 1988 ). Oak Ridge fault, Ventura fold belt, and the Sisar decollement, Ventura basin, California , Geology 16 , 1112 – 1116 . Yeats , R. S. , E. A. Keller , and K. R. LaJoie , ( 1982 ). Field trip number 3...
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