ABSTRACT Basal Triassic strata in the Saddlebag Lake pendant in the eastern Sierra Nevada, California, preserve a record of magmatism and sedimentation that marks the maturation of the early Mesozoic Cordilleran arc at this latitude. Facies analysis, geochemistry, and U-Pb geochronology provide the basis for a model that shows ways in which the types of volcanism and the geochemistry of magmatism reflect the presence and evolution of continental crust in the upper plate of a young subduction zone. Facies analysis of the breccia of Frog Lakes, an andesitic dome complex within the Saddlebag Lake pendant, demonstrates a subaqueous environment of deposition that is inferred to be characteristic of the interbedded tuff of Greenstone Lake and underlying rhyolitic tuff of Saddlebag Lake and conglomerate of Cooney Lake. This subaqueous volcanism and sedimentation suggest that subduction drag on the continental upper plate had greater effect than the buoyancy imparted by the felsic crust. Geochemistry of ignimbrites and dome deposits together with U-Pb isotopic and geochemical analyses of zircon from ignimbrites and the conglomerate of Cooney Lake and from similar-age strata from the Mount Morrison pendant to the south demonstrate the nature of upper-plate continental crust in the period between ca. 250 and ca. 220 Ma. Breccia clasts are medium-K tholeiitic arc basalt, basaltic andesite, and andesite, and they broadly overlap in bulk composition with underlying mafic hypabyssal intrusions. Minor- and trace-element geochemistry of tuff and detrital zircon grains indicates that Triassic silicic melts were relatively cool and fractionated, consistent with late zircon saturation in Zr-poor melts. We infer that the eruption and welding of thick, rhyolitic ignimbrites are, to first order, unique to magmas derived from subduction under continental crust.

The Peninsular Ranges batholith north of latitude 33°N consists of five distinctive longitudinal batholith zones. Four zones are autochthonous—a western zone, western transition zone, eastern transition zone, and an eastern zone. The fifth zone, the upper-plate zone, is allochthonous. The western zone, western transition zone, eastern transition zone, and eastern zone are contiguous products of Cretaceous subduction transitioning from a Mesozoic oceanic-arc setting to continental margin arc setting. Within the autochthonous zones, the nature and geochemistry of plutons record changes reflecting subduction proceeding from west to east over a 35 m.y. period. The allochthonous upper-plate zone is structurally located above the regional Eastern Peninsular Ranges mylonite zone. Host rocks for the western zone, western transition zone, and eastern transition zone are mostly Mesozoic, and host rocks of the eastern zone are Paleozoic. The composition of the plutons reflects changes in magma originating in shallow oceanic crust in the western zone to a deeper continental marginal setting in the eastern zone and upper-plate zone. Several aspects of the upper-plate zone rocks set them apart from the autochthonous batholithic rocks. Western zone magmatism occurred during an extensional subduction phase that involved Mesozoic oceanic crust. Plutons were emplaced passively from 126 Ma to 108 Ma, forming 47.9% of the area of the autochthonous batholith at a rate of 2.7% per million years. Geochemical variation is greater in the western zone than it is in the other zones. Rock compositions range from gabbro to high-SiO 2 granites; plutons in this zone contain magnetite as an accessory mineral. Most plutonic rocks have initial 87 Sr/ 86 Sr (Sr i ) values <0.7045, initial 206 Pb/ 204 Pb (Pb i ) <19, δ 18 O <9‰, and positive initial epsilon Nd (ε Ndi ). By 111 Ma, conditions for pluton emplacement began to change radically from extensional to compressional as subduction encountered older continental crust. The boundary between the western zone and western transition zone is marked clearly by a change in the magnetic properties, which are highly magnetic in the western zone to weakly magnetic in the transition zones. Western transition zone plutons, which have affinities with the western zone plutons, constitute 13.5% by area of the autochthonous batholith and formed over 13 m.y. at a decreased rate of batholith formation, 1% per million years. Plutons of the western transition zone are characterized by Sr i values of 0.7045–0.7050, δ 18 O <9‰, and positive ε Ndi . Deformation of the prebatholithic rocks was intense at 100 Ma, as the plutonism of the western transition zone ended and emplacement in the eastern transition zone began. From 99 to 93 Ma, the rate of magma emplacement accelerated, forming 2.4% per million years by area of the northern part of the autochthonous batholith. The eastern transition zone plutons, having affinities with the eastern zone plutons, have Sr i values of 0.7051–0.7057, δ 18 O >9‰, and negative ε Ndi . Most eastern transition zone plutons were emplaced in a less dynamic setting than the western transition zone plutons. By 98 Ma, subduction had transitioned eastward as plutons were emplaced in continental crust. The rate of magma emplacement increased to form the eastern zone over 7 m.y., or a rate of batholith growth of 3.4% per million years by area. There is considerable temporal overlap in the magma emplacement of the eastern transition zone and the eastern zone. Combined eastern transition zone and eastern zone magmatism produced 39% (by area) of the autochthonous batholith in 8 m.y. at a rate of ~5% per million years. The 102 Ma gabbro body is not considered in this analysis. Eastern zone plutons are characterized by Sr i >0.7060, mostly in the range of 0.7061–0.7076, Pb i >19, δ 18 O >9‰, and a large negative ε Ndi . The allochthonous granitic sheets that constitute the upper-plate zone include batholithic rocks ranging in age from 92 to 75 Ma; most are in the range of 86–75 Ma. These granitic rocks have a more restricted range of geochemistry than those in the other zones; they are magnetite-bearing rocks, unlike the ilmenite-bearing granitic rocks of the transition zones and eastern zone, and they have large negative ε Ndi , and Sr i in the range of 0.7076–0.7084. During the Late Cretaceous, the Eastern Peninsular Ranges mylonite zone developed in the eastern part of the Peninsular Ranges Province, deforming granitic rocks of the eastern part of the eastern zone. Following mylonitization, westward displacement on a series of low-angle thrust faults placed sheets of metamorphic and plutonic rock above the Eastern Peninsular Ranges mylonite zone, forming the upper-plate zone. Compatible elements decrease west to east across the batholith, and incompatible elements increase. Geochemical variation shows that magma forming the western part of the batholith had a shallow and primitive source compared with the eastern part, which had a deeper and more-evolved continental component. The frequency distribution of Sr i in the batholith is bimodal, having a peak of 0.7038 in the western zone, reflecting the oceanic crustal source, and a peak of 0.7072 in the eastern zone, reflecting increased incorporated continental crust sources. Only a small part of the batholith has Sr i values between 0.7055 and 0.7065, indicating a relatively sharp boundary between oceanic and continental crust. Linear arrays on Harker diagram indicate that geochemical variation within the batholith is from magma mixing and not magmatic differentiation. Our data are most simply explained by the Cretaceous arc transitioning from a Mesozoic oceanic-arc setting to a continental margin setting.

The Lakeview Mountains pluton is a concordant teardrop-shaped pluton located at a marked deflection of the structural grain of the prepluton rocks within the northern Peninsular Ranges batholith. This dynamically emplaced 100 Ma pluton lies within the western transition zone and consists of biotite-hornblende tonalite that lacks K-feldspar. The pluton is characterized by ubiquitous schlieren that range from black hornblende-biotite rock to near-white quartz-plagioclase rock, imparting an extreme outcrop-scale mineral and chemical heterogeneity to the pluton. Geometrically, the schlieren define three structural sets; one is concordant, and the other two constitute a northeast- and northwest-oriented conjugate set. The orientation of the concordant schlieren resulted from the outward expansion of the pluton, and the orientation of the conjugate set is in response to regional stresses at the time of emplacement. Based on chemical analysis of systematically collected samples, the pluton consists of two chemically distinct parts. Initially emplaced magma formed an ellipsoidal body concordant with the regional northwest structural grain. This early-emplaced magma formed a zoned body having a relatively potassic core and a mafic outer part. Later-emplaced magma expanded the pluton to the north-northeast, deflecting the regional structural grain of the batholith, and forming the teardrop-shaped outline of the composite pluton. The later-emplaced magma was more mafic than the initial magma, producing a more mafic core and a relatively higher-potassium outer part. Variations in major and trace elements, specific gravity, magnetic susceptibility, and magnetite content, in addition to aeromagnetic and pseudogravity anomalies, all show similar patterns within the pluton. Bodies of hypersthene gabbro, large masses of melanocratic and leucocratic tonalite, and numerous potassic granitic pegmatite dikes are concentrated in the more mafic part of the pluton, and interpreted as the last to crystallize. The leucocratic and melanocratic tonalite bodies are interpreted to be late-emplaced giant schlieren. Initial 87 Sr/ 86 Sr ratios (Sr i ) have only subtle, limited systematic variation, reflecting a relatively uniform magma source. Rb/Sr ratios also are relatively constant from the early- to late-emplaced magma, indicating the absence of, or only slight, fractional crystallization from the early- to late-emplaced magma. Sr i values of the hypersthene gabbro, mafic enclaves, and granitic pegmatites are the same as the tonalite of the pluton. The deflection of the regional structural grain by outward expansion of the pluton is interpreted to be a result of dynamic emplacement of the magma. Highly attenuated mafic enclaves in a prepluton mixed granitic rock unit that partly surrounds the pluton are also interpreted to have developed in response to outward expansion during the dynamic emplacement. A comb-layered gabbro, located along the contact of the earlier-formed part of the pluton, is interpreted as an early water-rich magma emplaced in a border area of the pluton protected from primary flow and dynamic strain. The high-potassium pegmatite bodies are interpreted to have formed from residual, immiscible, water-charged fluids derived from the low-potassium tonalite magma, which are concentrated in the mafic last part of the pluton to crystallize.

We present a newly compiled geologic map of the Pine Mountain window based on available 1:24,000 (and smaller) scale geologic maps; this map provides an improved basis to reconcile long-standing issues regarding tectonic evolution. We integrate sensitive high-resolution ion microprobe (SHRIMP) single-grain U-Pb ages of igneous, metamorphic, and detrital zircons from Grenville basement rocks, associated metasedimentary units, and cover rocks to help clarify the pre-Appalachian history and to better delimit the distribution of Laurentian versus peri-Gondwanan and Gondwanan units along the southeast flank of the window. U-Pb results indicate that some units, which earlier had been correlated with Neoproterozoic to Early Cambrian Laurentian rift deposits of the Ocoee Supergroup (i.e., Sparks-Halawaka Schist), actually are supracrustal rocks deposited prior to ~1100 Ma that were intruded and metamorphosed during the Ottawan phase of the Grenville orogeny. Zircons from the Phelps Creek Gneiss are 425 ± 7 Ma and overlap in time with plutons that intruded rocks of the Carolina superterrane during the Silurian (i.e., the Concord-Salisbury suite). The host units to the Phelps Creek Gneiss had also previously been interpreted as Sparks-Halawaka Schist, but field relations combine with the Silurian intrusive age to suggest that they rather belong to the peri-Gondwanan Carolina superterrane, helping to refine the position of the Central Piedmont suture in its most southern exposures. Results suggest that the Pine Mountain window is not framed by a single fault, but by Alleghanian faults of different timing, rheology, and kinematics, some of which were reactivated while others were not. The new map and U-Pb dates reveal that the southwesternmost exposures of the Central Piedmont suture are located farther northwest, so the width of the Pine Mountain window narrows from 22 km wide in central Georgia to only 5 km in Alabama. At its narrowest, the flanks of the Pine Mountain window are marked by two relatively thin normal faults (the Towaliga and Shiloh faults, northwest and southeast, respectively) that have excised the wider, earlier-formed mylonite zones. All of the Alleghanian faults are cut by later high-angle, normal and left- and right-slip brittle faults (Mesozoic?), which also influenced the present configuration of the window.

Abstract Two subparallel NNW-to NW-trending mineral belts in Nevada, the Battle Mountain-Eureka trend on the SW and the Carlin trend on the NE, are thought to reflect deep-seated, pre-Cenozoic crustal structures. These structures may be pre-Cenozoic faults, Mesozoic and/or Paleozoic fold axes, or uncertain features of the Precambian basement. Both geophysical and geochemical/isotopic studies can be used to complement field based geologic studies of these features. Geophysical studies measure time-integrated physical parameters and attempt to distinguish younger from older features. Isotopie studies have the advantage of investigating time-related features by comparing the isotopie compositions of rocks formed at different times during the geologic history of a region for systematic or significant changes or lack there of. The isotopie signatures of igneous rocks largely reflect the average characteristics of their source regions plus any later interaction with the crustal column through which they moved or into which they were emplaced, and in general reflect lower and middle crustal features. Kistler and Peterman (1973, 1978) and Kistler (1983, 1991) demonstrated that the distribution of Sr isotopie compositions of granitoid rocks in the northern Great Basin delineate crustal structure, particularly the location of the continental-oceanic crustal boundary as marked by the I sr = 0.706 line. Ellison et al. (1990) showed that the I sr =0.706 Ime is correlated with Paleozoic stratigraphy. Farmer and DePaolo (1983, 1984) used combined Nd and Sr isotopie compositions of Great Basin granitoids to study the pedogenesis of these rocks and regional crustal structure; however, these pioneering studies are limited by the