Experimental constraints on the role of dynamic recrystallization on resetting the Ti‐in‐quartz thermobarometer

Nachlas, William O.; Hirth, Greg

doi:10.1002/2015jb012274

Cited by 30 publications

(36 citation statements)

References 71 publications

(170 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Quartz grains with dark CL and low Ti content often are located in the vicinity of biotite and other secondary phases (Figures c and d). We infer that Ti equilibration was enhanced within the dark CL bands, due to local exchange of Ti with secondary phases during deformation [ Nachlas and Hirth , ]. In contrast, bright CL regions likely are characterized by Ti concentrations inherited from the regional foliation, which did not fully reequilibrate during deformation.…”

Section: New Temperature Constraints: Methods and Resultsmentioning

confidence: 99%

Comparison of thermal modeling, microstructural analysis, and Ti‐in‐quartz thermobarometry to constrain the thermal history of a cooling pluton during deformation in the Mount Abbot Quadrangle, CA

Nevitt

Warren

Kidder

et al. 2017

Geochem Geophys Geosyst

View full text Add to dashboard Cite

Granitic plutons commonly preserve evidence for jointing, faulting, and ductile fabric development during cooling. Constraining the spatial variation and temporal evolution of temperature during this deformation could facilitate an integrated analysis of heterogeneous deformation over multiple length‐scales through time. Here, we constrain the evolving temperature of the Lake Edison granodiorite within the Mount Abbot Quadrangle (central Sierra Nevada, CA) during late Cretaceous deformation by combining microstructural analysis, titanium‐in‐quartz thermobarometry (TitaniQ), and thermal modeling. Microstructural and TitaniQ analyses were applied to 12 samples collected throughout the pluton, representative of either the penetrative “regional” fabric or the locally strong “fault‐related” fabric. Overprinting textures and mineral assemblages indicate the temperature decreased from 400–500°C to <350°C during faulting. TitaniQ reveals consistently lower Ti concentrations for partially reset fault‐related fabrics (average: 12 ± 4 ppm) than for regional fabrics (average: 31 ± 12 ppm), suggesting fault‐related fabrics developed later, following a period of pluton cooling. Uncertainties, particularly in TiO2 activity, significantly limit further quantitative thermal estimates using TitaniQ. In addition, we present a 1‐D heat conduction model that suggests average pluton temperature decreased from 585°C at 85 Ma to 332°C at 79 Ma, consistent with radiometric age data for the field. Integrated with the model results, microstructural temperature constraints suggest faulting initiated by ∼83 Ma, when the temperature was nearly uniform across the pluton. Thus, spatially heterogeneous deformation cannot be attributed to a persistent temperature gradient, but may be related to regional structures that develop in cooling plutons.

show abstract

Section: New Temperature Constraints: Methods and Resultsmentioning

confidence: 99%

Comparison of thermal modeling, microstructural analysis, and Ti‐in‐quartz thermobarometry to constrain the thermal history of a cooling pluton during deformation in the Mount Abbot Quadrangle, CA

Nevitt

Warren

Kidder

et al. 2017

Geochem Geophys Geosyst

View full text Add to dashboard Cite

show abstract

“…). Before the experiment, silica gel samples were calcined in a Pt crucible at 825 °C for 1 h, following the methods described by Luan and Paterson () and Nachlas and Hirth (). Layered aggregates were prepared by cold pressing the predried silica gel into a Ni capsule with Fe spacers (spacers only used in the seven‐layer experiment), which was inserted into an outer Fe jacket and sandwiched by alumina pistons.…”

Section: Methodsmentioning

confidence: 99%

“…This study used the Paterson gas-medium apparatus at the University of Minnesota to hot-press three-and seven-layer aggregates of doped silica gels at 1100°C and 300 MPa for 1-3 h (following a procedure similar to Tasaka et al 2015). Before the experiment, silica gel samples were calcined in a Pt crucible at 825°C for 1 h, following the methods described by Luan and Paterson (1992) and Nachlas and Hirth (2015). Layered aggregates were prepared by cold pressing the predried silica gel into a Ni capsule with Fe spacers (spacers only used in the seven-layer experiment), which was inserted into an outer Fe jacket and sandwiched by alumina pistons.…”

Section: Experimental Methodsmentioning

confidence: 99%

Precise and Accurate Doping of Nanoporous Silica Gel for the Synthesis of Trace Element Microanalytical Reference Materials

Nachlas

2016

Geostandard Geoanalytic Res

View full text Add to dashboard Cite

This paper presents an experimental procedure for fabricating high-purity silica glass that contains a selected element at a specified concentration. This technique is used to prepare glasses doped with trace-level concentrations of Ti with the goal of improving analytical confidence when measuring trace elements in quartz. Systematic tests were performed to determine the ideal conditions and procedures for doping nanoporous silica gel with the highest efficiency of dopant recovery. Silica gel was cleaned in concentrated HCl, immersed in a non-polar doping medium at a controlled pH and doped with precise quantities of ICP-MS standard solution. Using liquids composed of longer chain molecules as the doping medium diminishes recovery, suggesting that large molecules could obstruct nanopores to inhibit capillary uptake of the dopant. A control experiment using crystalline quartz reinforced the effectiveness of nanoporous silica gel for doping with trace-level precision. Layered aggregates of silica gel doped with different Ti concentrations were hot-pressed to create multi-layered reference materials that were analysed with multiple techniques at a variety of spatial scales. Analyses at the intra-grain scale (SEM-CL, EPMA), at the single grain scale (SIMS), at the sample layer scale (EPMA, LA-ICP-MS), and at the bulk scale (ICP-OES) demonstrate acceptable homogeneity at the analyte volumes characteristic of most microanalysis techniques and show that nanoporous silica gel holds promise as a highly retentive doping substrate for preparing trace element reference materials for laser-, electron-and ion-beam microanalysis.

show abstract

“…In both experimental and natural deformation, Ti concentrations in quartz are often reset during recrystallization (e.g. Behr and Platt, 2011;Kidder et al, 2013;Kohn and Northrup, 2009;Nachlas and Hirth, 2015;Nachlas et al, 2014). While quantifying temperatures using Ti-in-quartz thermobarometry is complicated by uncertainty in Ti 10 activity (Bestmann and Pennacchioni, 2015;Grujic et al, 2011;Nevitt et al, 2017) and differing calibrations (Huang and Audétat, 2012;Thomas et al, 2015), we find that variations in Ti-in-quartz concentrations in Alpine Fault rocks span a range large enough that these issues can be largely bypassed using independent constraints on maximum and minimum temperatures associated with quartz recrystallization.…”

Section: Introductionmentioning

confidence: 97%

Constraints on Alpine Fault (New Zealand) Mylonitization Temperatures and Geothermal Gradient from Ti-in-quartz Thermobarometry

Kidder¹,

Toy²,

Prior³

et al. 2018

Preprint

View full text Add to dashboard Cite

Abstract.We constrain the thermal state of the central Alpine Fault using approximately 750 Ti-in-quartz SIMS analyses from a 10 suite of variably deformed mylonites. Ti-in-quartz concentrations span more than an order of magnitude from 0.24 to ~5 ppm, suggesting recrystallization of quartz over a 300° range in temperature. Most Ti-in-quartz concentrations in mylonites, protomylonites, and the Alpine Schist protolith are between 2 and 4 ppm and do not vary as a function of grain size or bulk rock composition. Analyses of 30 large, inferred-remnant quartz grains (>250 µm), as well as late, cross-cutting, chlorite-bearing quartz veins also reveal restricted Ti concentrations of 2-4 ppm. These results indicate that the vast majority of Alpine Fault 15 mylonitization occurred within a restricted zone of pressure-temperature conditions where 2-4 ppm Ti-in-quartz concentrations are stable. This constrains the deep geothermal gradient from the moho to about 8 km to a slope of 5 °/km. In contrast, the small grains (10-40 µm) in ultramylonites have lower Ti concentrations of 1-2 ppm, indicating a deviation from the deeper pressuretemperature trajectory during the latest phase of ductile deformation. These constraints suggest an abrupt, order of magnitude change in the geothermal gradient to an average of about 60 °/km at depths shallower than about 8 km, i.e. within the 20 seismogenic zone. Anomalously, the lowest-Ti quartz (0.24-0.7 ppm) occurs away from the fault in protomylonites, suggesting that the outer fault zone experienced minor plastic deformation late in the exhumation history when more fault-proximal parts of the fault were deforming exclusively by brittle processes.

show abstract

Experimental constraints on the role of dynamic recrystallization on resetting the Ti‐in‐quartz thermobarometer

Cited by 30 publications

References 71 publications

Comparison of thermal modeling, microstructural analysis, and Ti‐in‐quartz thermobarometry to constrain the thermal history of a cooling pluton during deformation in the Mount Abbot Quadrangle, CA

Comparison of thermal modeling, microstructural analysis, and Ti‐in‐quartz thermobarometry to constrain the thermal history of a cooling pluton during deformation in the Mount Abbot Quadrangle, CA

Precise and Accurate Doping of Nanoporous Silica Gel for the Synthesis of Trace Element Microanalytical Reference Materials

Constraints on Alpine Fault (New Zealand) Mylonitization Temperatures and Geothermal Gradient from Ti-in-quartz Thermobarometry

Contact Info

Product

Resources

About