Eocene and Miocene extension, meteoric fluid infiltration, and core complex formation in the Great Basin (Raft River Mountains, Utah)

Abstract Metamorphic core complexes (MCCs) in the North American Cordillera reflect the effects of lithospheric extension and contribute to crustal adjustments both during and after a protracted subduction history along the Pacific plate margin. While the Miocene‐to‐recent history of most MCCs in the Great Basin, including the Raft River‐Albion‐Grouse Creek MCC, is well documented, early Cenozoic tectonic fabrics are commonly severely overprinted. We present stable isotope, geochronological ( 40 Ar/ 39 Ar), and microstructural data from the Raft River detachment shear zone. Hydrogen isotope ratios of syntectonic white mica ( δ 2 H ms ) from mylonitic quartzite within the shear zone are very low (−90‰ to −154‰, Vienna SMOW) and result from multiphase synkinematic interaction with surface‐derived fluids. 40 Ar/ 39 Ar geochronology reveals Eocene (re)crystallization of white mica with δ 2 H ms  ≥ −154‰ in quartzite mylonite of the western segment of the detachment system. These δ 2 H ms values are distinctively lower than in localities farther east ( δ 2 H ms  ≥ −125‰), where 40 Ar/ 39 Ar geochronological data indicate Miocene (18–15 Ma) extensional shearing and mylonitic fabric formation. These data indicate that very low δ 2 H surface‐derived fluids penetrated the brittle‐ductile transition as early as the mid‐Eocene during a first phase of exhumation along a detachment rooted to the east. In the eastern part of the core complex, prominent top‐to‐the‐east ductile shearing, mid‐Miocene 40 Ar/ 39 Ar ages, and higher δ 2 H values of recrystallized white mica, indicate Miocene structural and isotopic overprinting of Eocene fabrics.