ABSTRACT Determining the origin and evolution of basin-and-range geomorphology and structure in the western United States is a fundamental problem with global implications for continental tectonics. Has the extensional tectonic development of the Great Basin been dominated by steeply dipping (horst and graben) faulting or detachment faulting? The purpose of this paper is to provide evidence that attenuation due to multiple coalescing detachment faults has been a significant or dominant upper-crustal process in at least some areas of the Great Basin. We present mapping at a scale of 1:3000 and seismic refraction profiling of an area at the discontinuity between the White Pine and Horse Ranges, east-central Nevada, USA, which indicate the existence of a detachment rooted in an argillaceous ductile unit. This fault, which we call the Currant Gap detachment, coalesces with the previously mapped regional White Pine detachment. Our data suggest that the Currant Summit strike-slip fault at the surface, previously proposed to explain a nearly 2500 m east-west surface offset between the two ranges, likely does not exist. If a discontinuity exists at depth, it could be manifested at the surface by the undulating topography of the two coalescing detachments. On the other hand, offset domal uplifts in the two ranges would obviate the need for any lateral discontinuity at depth to explain the observed surface features. Our previous mapping of the White Pine detachment showed that it extends over the White Pine, Horse, and Grant Ranges and into Railroad Valley (total of 3000 km 2 ). Accordingly, we propose a model of stacked, coalescing detachments above the metamorphic infrastructure; these detachments are regional and thus account for most of the basin-range relief and upper-crust extension in this area. An essential feature of our model is that these detachments are rooted in ductile units. Detachments that have been observed in brittle units could have initiated at a time when elevated temperatures or fluid flow enhanced the ductility of the rocks. The Currant Gap and White Pine detachments exhibit distinctive types of fluid-genetic silicified rocks. Study of such rocks in fault contacts could provide insights into the initiation and early history of detachment faulting as well as the migration of fluids, including petroleum.

Abstract Study of shear zones and associated basins within an oblique rift can shed light on the development of a young transform continental margin. San Pedro Basin lies within the Inner Borderland Rift offshore southern California, where it is bisected by the San Pedro Basin Fault (SPBF). Based on seismic reflection and multibeam bathymetry data, we show that the SPBF attained continuity with the San Diego Trough Fault (SDTF) between 1 Ma and 800 ka, to form a 350-km-long shear zone. Prior to that time, the SDTF was linked to the Catalina Fault, forming a restraining bend that contributed to the uplift of Catalina Ridge. Seismically defined depositional sequences in San Pedro Basin record a multistage history of uplift and subsidence for the basin. Young, flat-lying sequences filling a sigmoidal depocenter indicate that subsidence has been occurring since about 1 Ma. This date is corroborated by a series of submarine lowstand depositional terraces surrounding Santa Catalina Island. A 5 Ma to 1 Ma progressively tilted sequence, onlapped by the flat-lying strata, is confined to the present basin. Folded sequences older than ca. 5 Ma extend beyond the present basin onto Catalina Ridge and are correlated to Mohnian and Luisian strata on Santa Catalina Island and Palos Verdes Peninsula. From these data, we interpret the growth history of San Pedro Basin to involve at least three successive, nested basins. The first, which we call the “San Pedro (SP) protobasin,” formed before 5 Ma and was of indeterminate size, including within its boundaries areas flanking the current basin that were subsequently uplifted, Catalina Ridge and Palos Verdes Anticlinorium. Between 5 Ma and 1 Ma, approximately, a second basin, nested within the first, formed as the two flanking structural highs initiated. Finally, a third basin, nested within the first two, began to form when the SPBF–SDTF link was established and rapid local subsidence began; this is the depocenter of the current San Pedro Basin, and its southwestern boundary is occupied by the trace of the SPBF. Our model of basin formation begins with the initial oblique Inner Borderland (IB) Rift, which formed during rotation and translation of crustal blocks away from the continental margin (about 20 Ma). The IB Rift was segmented due to preexisting structural configurations. Published reconstructions show that the SP protobasin was originally in a narrow zone flanked by active volcanoes. Continued extension widened and deepened the rift, while volcanism continued along the flanks of the rift until about 10 Ma. As the rift widened, nested basins formed within the original protobasins along the axis of the rift. These basins were later fragmented (after 5 Ma for the SP protobasin) by transpressive processes associated with the shift of the transform plate boundary to the southern San Andreas Fault. New nested basins also formed during this time as shear zones reorganized to shortcut restraining geometries.

Abstract Seismic mapping indicates that Lasuen Knoll in the Inner Borderland, offshore southern California, is a pop-up structure associated with a restraining stepover of the Palos Verdes Fault. Dextral shear is apparently transferred southeast through a complex zone of faults that includes the Carlsbad Ridge and Coronado Bank faults. This model is supported by comparison with other pop-up structures in the Inner Borderland and analogs to published sandpack laboratory simulations. The Palos Verdes Fault along Lasuen Knoll has existed at least since the late Miocene Epoch (5 to 8 Ma) and is contemporaneous with the segment of the Palos Verdes Fault on San Pedro Shelf and adjacent to the Palos Verdes Peninsula. Isochore maps of stratigraphic intervals indicate that extension occurred locally along the Palos Verdes Fault adjacent to the present Lasuen Knoll pop-up during the Mohnian Stage and became more widespread during the Delmontian Stage (approximately 7.5 to 5 Ma). Repettian strata onlapping Lasuen Knoll indicate that the knoll began to form as a pop-up structure by the early Repettian (entire stage approximately 5 to 2.3 Ma) and has been active possibly until the Holocene. Transtensional zones occur along the Palos Verdes–Carlsbad Ridge–Coronado Bank Fault Zone north and south of Lasuen Knoll. The San Gabriel Transtensional Zone, north of Lasuen Knoll, separates the knoll from the Palos Verdes Anticlinorium, the other major uplift structure along the Palos Verdes Fault. The Lasuen Knoll basement high, the overall structural high that includes Lasuen Knoll, is similar in dimension and shape to the Palos Verdes Anticlinorium, which has been interpreted to be underlain by a low-angle ramp fault. Recent models of low-angle ramp faults as major causes of the uplift of Palos Verdes, however, cannot be readily applied to Lasuen Knoll.