ABSTRACT Hafnium isotope ratios in Late Jurassic zircon from the Summit Gabbro provide geochemical evidence for rifting at ca. 148 Ma through the southern Sierra Nevada arc crust. Previous evidence for intra-arc extension includes a linear distribution of early Mesozoic volcano-sedimentary deposits located within the regional footprint of the ~600-km-long Independence dike swarm. In this study, latest Jurassic rifting through the entire thickness of the arc crust is supported by an abrupt, 40-εHf i -unit isotopic pull-up that records the incorporation of depleted-mantle partial melts into basaltic magmas that rapidly migrated into the upper arc crust. Isotopic context for this latest Jurassic pull-up is provided by Permian through Cretaceous zircon xenocrysts sampled by ca. 85–78 Ma dikes and sills that sampled the crust underlying the eastern Sierra Nevada range crest. Summit Gabbro bodies define a northwest-trending lineament paralleling the Kern Plateau shear zone, a geometry consistent with previous interpretations that the Kern Plateau shear zone originated as a late Paleozoic sinistral transform fault that evolved to a normal fault accommodating early Mesozoic intra-arc extension. New zircon U-Pb geochronology data coupled with field observations and whole-rock geochemistry serve as the basis to reclassify Summit gabbros and diorites as latest Jurassic and to motivate definition of the bimodal Summit igneous complex (151.0 ± 1.7–146.1 ± 1.2 Ma; N = 15) as also including coeval gabbro-granite dikes of the Osa Creek ring complex and the newly defined Tübatulabal hypabyssal-volcanic series. Tight age constraints support correlation of the Summit igneous complex to the regionally extensive, ca. 148 Ma Independence dike swarm. Multiple lines of evidence support latest Jurassic Sierran arc magmagenesis within a north-northwest–trending, sinistral transtensional regime, including: (1) subparallel orientations of the Independence dike swarm and aligned Summit Gabbro intrusions; (2) overlapping and bimodal compositions in both suites; and (3) the dramatic Hf isotope pull-up in zircons from Summit gabbro-diorites, recording a short-lived increase in the proportion of isotopically primitive mafic magmas intruding into the shallow arc crust. Though clearly differentiated, the composition of one gabbroic dike is the most primitive composition reported in the Sierra Nevada arc to date. The footprint of an intra-arc graben produced by early Mesozoic extension in eastern California is constrained by the Independence dike swarm, the Kern Plateau shear zone, and the Summit igneous complex, along with distributions of Triassic–Jurassic volcano-sedimentary deposits. Coupling the history of motion along the Kern Plateau shear zone with evidence for local extension beginning in the Permian–Triassic arc, we hypothesize that Mesozoic intra-arc faulting was strongly influenced by north-northwest–trending structures inherited from a mid- to late Paleozoic sinistral transpressional-transtensional plate boundary that extended for thousands of kilometers along the western boundary of Laurentia. We assemble a Permian–Jurassic time line of intra-arc extension within the plate margin locally transitioning from sinistral transform to convergent, one that culminated in latest Jurassic rifting through the entire crust underlying the Kern Plateau.

Late Triassic through Early Cretaceous detrital zircon separated from Lower Cretaceous sedimentary strata provides a record of arc magmatism that is not obscured by products of the mid- to Late Cretaceous surge, which dominate the exposed Sierra Nevada batholith. Matching U-Pb age-probability maxima to U-Pb dates of exposed arc plutonic rocks provides confirmation that the detrital zircon was sourced in the erupting and eroding Sierra Nevada arc. These data suggest that magmatic productivity in the southwestern arc increased steadily through the Middle Jurassic, from an Early Jurassic lull through the Late Jurassic. The detrital-zircon record documents an original footprint of the Early Cretaceous arc extending from its current exposure in the western Sierra Nevada foothills northwestward into the eastern Sacramento Valley, where its relatively mafic roots are presumably buried beneath younger sedimentary strata infilling the Great Valley. The sparse record of Late Triassic magmatism preserved in the analyzed intra-arc and forearc deposits likely reflects greater separations in both time and space between the Early Cretaceous basins and the Triassic arc. Analysis of an atypically dense sample set from the Goldstein Peak Formation intra-arc basin deposits, in conjunction with new data from the Lower Cretaceous Gravelly Flat Formation and published data from other Lower Cretaceous forearc strata of the Great Valley Group, suggests that an even greater density and broader geographic distribution of detrital-zircon samples are needed to more completely reconstruct the record of arc magmatism.

Abstract Petrologic, structural, geochronologic, and geochemical data from rocks exposed in the western foothills of the Sierra Nevada batholith just south of the western Foothills metamorphic belt (the Stokes Mountain region) provide new insight regarding several poorly understood aspects of the development of the compound Sierra Nevada arc. Exposures of three different metasedimentary packages together document transitions in the depositional environments present along the outboard edge of this arc segment throughout the Mesozoic Era, culminating in the emergence of the Cretaceous continental margin arc. Exposures of mafic cumulates and associated differentiates of the Early Cretaceous batholith permit investigation into the earliest stages of differentiation of depleted-mantle–derived arc magmas. Together with the surrounding Kings-Kaweah ophiolite belt, these Mesozoic plutonic and metasedimentary rocks are proposed to form an analog for the crystalline basement underlying much of the eastern half of the Great Valley forearc basin.

Abstract Southeastward beyond the southern termination of the Sierran Foothills metamorphic belt, metamorphic pendants of Paleozoic ophiolitic basement are intruded by Middle Jurassic to Early Cretaceous, mafic-to-intermediate plutonic rocks. These rocks constitute a record of the various plutonic environments that were active along the western North American margin during the middle Mesozoic: a Middle Jurassic ensimatic arc, a Late Jurassic, Nevadan-age, transpressional-transtensional regime, and an emergent, Early Cretaceous continental-margin arc. In detail, these plutonic suites reveal the roles that both pre-and synmagmatic structures—such as Paleozoic transform faults, Nevadan-age regional sutures, and localized Cretaceous crustal tears—played in focusing magmatism. Taken together, outcrops of the Kings River ophiolite, the Owens Mountain dike swarm, and the Stokes Mountain ring dike complexes reveal a sequence of tectonic and magmatic processes through which accreted oceanic lithosphere was transformed into continental crust .