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1. Role of fluids on deformation in mid-crustal shear zones, Raft River Mountains, Utah

   https://doi.org/10.1017/S0016756822000231  

   Gottardi, Raphaël; Hughes, Brendan (January 2022, Geological Magazine)

   Abstract Fluids are commonly invoked as the primary cause for weakening of detachment shear zones. However, fluid-related mechanisms such as pressure-solution, reaction-enhanced ductility, reaction softening and precipitation of phyllosilicates are not fully understood. Fluid-facilitated reaction and mass transport cause rheological weakening and strain localization, eventually leading to departure from failure laws derived in laboratory experiments. This study focuses on the Miocene Raft River detachment shear zone in northwestern Utah. The shear zone is localized in the Proterozoic Elba Quartzite, which unconformably overlies the Archaean basement, and consists of an alternating sequence of quartzite and muscovite-quartzite schist. In this study, we characterize fluid-related microstructures to constrain conditions that promoted brittle failure in a plastically deforming shear zone. Thin-section analyses reveal the presence of healed microcracks, transgranular fluid inclusion planes and grain boundary fluid inclusion clusters. Healed microcracks occur in three sets, one sub-perpendicular to the mylonitic foliation, and a set of two conjugate microcracks oriented at ∼40–60° to the mylonitic foliation. Healed microfractures are filled with quartz, which has a distinct fabric, suggesting that microcracks healed while the shear zone was still at conditions favourable for quartz crystal plasticity. Transgranular fluid inclusion planes also occur in three sets, similar in orientation to the healed microfractures. Fluid inclusions commonly decorate grain and subgrain boundaries as inter- and intragranular clusters. Our results document ductile overprint of brittle microstructures, suggesting that, during exhumation, the Raft River detachment shear zone crossed the brittle–ductile transition repeatedly, providing pathways for fluids to permeate through this shear zone. 

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2. Effect of Water‐Rock Ratio on the Stable Isotope Record of Fluid‐Rock‐Deformation Interactions in Detachment Shear Zone

   https://doi.org/10.1029/2023GC011340  

   Gottardi, Raphaël; Mire, Camron; Davis, Niya; Casale, Gabriele (May 2024, Geochemistry, Geophysics, Geosystems)

   Abstract Oxygen and hydrogen stable isotope analyses of quartz and muscovite veins from the footwall of the Raft River detachment shear zone (Utah) provide insight into the hydrology and fluid‐rock interactions during ductile deformation. Samples were collected from veins containing 90%–100% quartz with orientations either at a high angle or sub‐parallel to the surrounding quartzite mylonite foliation. Stable isotope analysis was performed on 10 samples and compared with previous quartzite mylonite isotope data sets. The results indicate that the fluid present during deformation of the shear zone was meteoric in origin, with a δ²H value of approximately −100‰ and a δ¹⁸O value of approximately −13.7‰. Oxygen stable isotope O¹⁸O depletion correlates with the muscovite content of the analyzed rocks. Many of the analyzed samples in this and other studies show an apparent lack of equilibrium between the oxygen and hydrogen isotope systems, which can be explained by hydrogen and oxygen isotope exchange at varying fluid‐rock ratios. Our results suggest that the Raft River detachment shear zone had a low static fluid‐rock ratio (<0.1), yet experienced episodic influxes of fluids through semi‐brittle structures. This fluid was then expelled out into the surrounding mylonite following progressive shearing, causing further¹⁸O‐depletion and fluid‐related embrittlement. 

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3. RHEOLOGY OF COEVAL MYLONITE AND PSEUDOTACHYLYTE IN THE BRITTLE-DUCTILE TRANSITION OF THE BLACK BELT SHEAR ZONE, SOUTHERN CALIFORNIA BATHOLITH

   https://doi.org/10.1130/abs/2024AM-403529  

   Castro_Mendez, Anya; Miranda, Elena; Schwartz, Joshua; Klepeis, Keith A (January 2024, Geological Society of America)

   We investigate the deformation conditions of coeval mylonites and pseudotachylytes (pst) exposed in the brittle-ductile transition (BDT) in the Black Belt Shear Zone (BBSZ) in the Southern California Batholith using SEM (Scanning Electron Microscope) imaging, and Electron Backscatter Diffraction (EBSD) analysis. We selected four representative samples along a strain gradient of the BBSZ. The BBSZ is a transpressional shear zone developed within hornblende and biotite tonalites and diorites. The shear zone is discontinuous over a ~ 1.5 - 2 km wide zone, and kinematic indicators show oblique top-to-SW, sinistral-reverse to thrust-sense motion. Metamorphic titanite grains aligned within the mylonitic fabric date the deformation to ~ 83 Ma. SEM and EBSD data show mm-thick seams of pst contained within and parallel to mylonitic foliation, and mutually overprinting relationships between brittle and plastic deformation. We observe a brittle overprint of mylonitic fabric in sample 46 and fractured porphyroclasts reworked into mylonitic fabric in samples 45 and 47. EBSD maps from sample 45 and 47 show decreasing modal percentages of hydrous mafic minerals (biotite and hornblende) in the mylonites with proximity to pst seams, suggesting these melted to form pst. In pst seams, there are embayed and rounded/elliptical plagioclase survivor clasts and acicular and aligned biotite microlites parallel to mylonitic fabric (45 & 47). EBSD maps show pst survivor clasts with the same shear sense as the mylonitic fabric, suggesting co-development. Pole figures show weak CPO in hornblende and plagioclase of sample 46. Samples 45 and 47 have no CPO present in plagioclase, however samples 45, 46, and 47 show strong CPO patterns for quartz that are consistent with prism slip. We interpret dislocation creep as the deformation mechanism accommodating plastic deformation in host mylonites. Quartz CPO patterns provide evidence of mylonitic deformation at temperatures ~ 600o C, and the presence of plagioclase survivor clasts as evidence of pst temperatures of ~1100oC. The kinematically consistent sense of shear between pst and host mylonitic fabrics suggests coeval development that indicate shifts from brittle to ductile deformation. Our results suggest periodic pst-generating events involving melting of hydrous mafic minerals aided the development of coeval mylonites and pst in the BDT. 

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4. The Black Belt Shear Zone records the earthquake cycle at the brittle-ductile transition: implications for the SCEC Community Rheology Model

   Elena Miranda, Joshua Schwartz (September 2023, Poster Presentation at 2023 SCEC Annual Meeting)

   Abstract. The inception of the Laramide Orogeny in Southern California is marked by a Late Cretaceous arc flare-up in the Southern California Batholith (SCB) that was temporally and spatially associated with syn-plutonic development of a regionally extensive, transpressional shear zone system. This ~200 km-long system is the best analog for the shear zones that extend into the middle crust beneath the major lithotectonic block-bounding faults of the San Andreas Fault system. We focus on the Black Belt Shear Zone, which preserves an ancient brittle-ductile transition (BDT), and is exposed in the SE corner of the San Gabriel lithotectonic block. The mid-crustal Black Belt Shear Zone forms a ~1.5-2 km thick zone of mylonites developed within hornblende and biotite tonalites and diorites. Mylonitic fabrics strike SW and dip moderately to the NW, and kinematic indicators from the Black Belt Shear Zone generally give oblique top-to-SW, sinistral thrust-sense motion (present-day geometry). U-Pb zircon ages of host rock to the Black Belt mylonites demonstrate crystallization at ~86 Ma and metamorphism at ~79 Ma at temperatures ~753 ¡C. Syn-kinematic, metamorphic titanite grains aligned with mylonitic foliation in the Black Belt Shear Zone give an age of ~83 Ma. These data indicate syn-magmatic sinistral-reverse, transpressional deformation. The BDT rocks in the Black Belt Shear Zone are characterized by a ~10 m-thick section of high strain mylonites interlayered with co-planar cataclasite and pseudotachylyte (pst) seams. Microstructural and electron backscatter diffraction (EBSD) analysis shows that the mylonites and cataclasites are mutually overprinted, and pst seams are overprinted by mylonitic fabric development. Pst survivor clasts show the same shear sense as the host mylonite, and this kinematic compatibility demonstrates a continuum between brittle and ductile deformation that is punctuated by high strain rate events resulting in the production of frictional melt. EBSD analysis reveals a decreasing content of hydrous maÞc mineral phases in host mylonite with increasing proximity to pst seams. This suggests that pst was generated by melting of hornblende and/or biotite, implying that coeval development of mid-crustal mylonites and pst does not require anhydrous melting conditions. Rather, the production of pst may liberate water, implying that BDT rock rheology is affected by transient pulses of water inßux and strain rate increases. 

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5. Evidence for transpression in the Picuris orogen: The deformation record of the Marqueñas Formation metaconglomerate, Picuris Mountains, New Mexico, USA

   https://doi.org/10.1130/GES02805.1  

   Bonamici, Chloë; Sulthaus, Danielle (January 2025, Geosphere)

   Abstract The most recent models for the Mesoproterozoic (ca. 1.5–1.35 Ga) Picuris-Baraboo-Pinware orogeny call on transpression resulting from oblique, diachronous convergence at the southern margin of Laurentia to explain the patterns of deformation and magmatism along this transcontinental belt. The Marqueñas Formation metaconglomerate provides a rare opportunity to directly study the strain and kinematics of deformation within the intraplate Picuris segment of the orogen. Statistical analysis of deformed quartzite pebble and boulder dimensions shows flattening strain at the outcrop to map scale (kilometers to meters). Quartz crystallographic preferred orientation (CPO) records a combination of flattening and non-coaxial shear at the intraclast scale (millimeters to micrometers). Kinematic vorticity axes, determined by crystallographic vorticity analysis on quartzite clasts, are well preserved despite widespread static recrystallization and align with principal strain axes determined from quartz CPO. The compatibility of strain and kinematic vorticity data indicates that flattening was produced in progressive, 3-D general shear. Outcrop-scale and map-scale structural relations link Marqueñas Formation flattening strain to oblique slip, with components of north-directed thrusting and dextral shear, on the Plomo-Pecos shear zone. Quartz flattening CPO yields predominantly crossed-girdle c-axis figures with opening angles of 69°–92° and a mean of 80°. Quartz c-axis opening angle thermometry yields deformation temperatures of 601 ± 50 °C, suggesting that flattening was synchronous with prograde to peak metamorphism during the second phase of deformation (D2) in the Picuris Mountains. We conclude that flattening of the Marqueñas Formation records inclined transpression within the Picuris orogen, consistent with oblique convergence along the Mesoproterozoic Laurentian plate margin. 

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