Water redistribution in experimentally deformed natural milky quartz single crystals—Implications for H<sub>2</sub>O‐weakening processes

Stünitz, Holger; Thust, Anja; Heilbronner, Renée; Behrens, Harald; Kilian, Rüdiger; Tarantola, Αlexandre; Gerald, J. D. Fitz

doi:10.1002/2016jb013533

Cited by 53 publications

(71 citation statements)

References 112 publications

(301 reference statements)

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“…The water contents of MT samples and other quartz mylonites deformed at greenschist conditions are comparable to (and even larger than) those of wet varieties of synthetic and natural milky quartz (350-4000 ppm) that exhibit water weakening in laboratory studies (e.g., Griggs and Blacic, 1965;Kekulawala et al, 1978;Stünitz et al, 2017). Highly deformed ribbon quartz grains, less deformed quartz augen, and recrystallized quartz grains of the MT exhibit OH bands of similar character to those of quartzites deformed in laboratory experiments, a result that validates applications of wet quartzite rheologies to evaluate rates of dislocation creep in middle to upper crustal shear zones (e.g., Hirth et al, 2001;Behr and Platt, 2011;Law, 2014).…”

Section: Water Weakening In Nature?mentioning

confidence: 89%

“…MT quartz spectra show a broad OH stretching band at 3400 cm −1 of large but variable magnitude (Fig. 2a), characteristic of molecular water in fluid inclusions of milky quartz (Kekulawala et al, 1978;Stünitz et al, 2017). In addition to this absorption band, some quartz grains from MT samples show an additional absorption band (or subtle shoulder) at ∼ 3600 cm −1 (Fig.…”

Section: Ftirmentioning

confidence: 99%

“…We know little of this early brittle deformation, but these fluid inclusion arrays have microstructures similar to those generated during hydrothermal diffusional healing of cracks (Smith and Evans, 1984;Beeler and Hickman, 2015). As a result, early brittle deformation, infiltration of water along open cracks, and crack healing appear to be important to the early introduction of water to quartz grain interiors (Kronenberg et al, 1986FitzGerald et al, 1991;Diamond et al, 2010;Tarantola et al, , 2012Stünitz et al, 2017).…”

Section: Wide Variations In Oh Contentmentioning

confidence: 99%

“…Processes of fluid inclusion decrepitation under deviatoric stresses have been studied experimentally , 2012, Stünitz et al, 2017, and they include simultaneous shrinkage of coarse (> 10 µm, optical-scale) inclusions, generation of dislocations at fluid inclusion walls, and formation of a new population of very fine (< 100 nm) fluid inclusions (visible only by transmission electron microscopy), which reside at dislocations and resemble water clusters and inclusions of deformed and heat-treated synthetic quartz (McLaren and Hobbs, 1972;White, 1973;Kirby and McCormick, 1979;Christie and Ord, 1980). The loss of coarse fluid inclusions and growth of fine inclusions require diffusive transport, which may occur along interconnected and mobile dislocations (McLaren et al, 1983Cordier et al, 1988Cordier et al, , 1994Jansen, 1990, 1994;Hollister, 1990;Tarontola et al, 2010Tarontola et al, , 2012Stünitz et al, 2017). Once formed, very fine fluid inclusions may also coarsen by pipe diffusion and processes documented by McLaren et al (1983) and Cordier et al (1988), leading to continuous changes in inclusion densities and size distributions.…”

Section: Wide Variations In Oh Contentmentioning

confidence: 99%

“…The effects of water on dislocation creep of quartz, including the nucleation, glide, climb and recovery of dislocations, and recrystallization are well known from (1) experimental studies of natural crystals, in which water was introduced into grain interiors (e.g., Griggs, 1967;Blacic, 1975Blacic, , 1981FitzGerald et al, 1991), (2) studies of synthetic and natural quartz varieties with large initial water contents (e.g., Griggs and Blacic, 1965;Hobbs, 1968;Baeta and Ashby, 1970;Kekulawala et al, 1978;Kirby and McCormick, 1979;McLaren et al, 1983;Linker et al, 1984;Gerretsen et al, 1989;Muto et al, 2011;Holyoke and Kronenberg, 2013;Stünitz et al, 2017), and (3) quartzites and polycrystalline quartz aggregates with water added or removed before or during experiments (e.g., Jaoul et al, 1984;Kronenberg and Tullis, 1984;Tullis and Yund, 1989;Hirth and Tullis, 1992;Gleason and Tullis, 1995;Post et al, 1996;Chernak et al, 2009). IR spectroscopy has played a key role in experimental studies of water weakening, through the characterization and measurement of OH absorption bands due to different hydrogen defects and forms of molecular water within quartz interiors (e.g., Kats, 1962;Griggs and Blacic, 1965;Stipp et al, 2006).…”

Section: Introductionmentioning

confidence: 99%

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Synchrotron FTIR imaging of OH in quartz mylonites

et al. 2017

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Abstract. Previous measurements of water in deformed quartzites using conventional Fourier transform infrared spectroscopy (FTIR) instruments have shown that water contents of larger grains vary from one grain to another. However, the non-equilibrium variations in water content between neighboring grains and within quartz grains cannot be interrogated further without greater measurement resolution, nor can water contents be measured in finely recrystallized grains without including absorption bands due to fluid inclusions, films, and secondary minerals at grain boundaries.Synchrotron infrared (IR) radiation coupled to a FTIR spectrometer has allowed us to distinguish and measure OH bands due to fluid inclusions, hydrogen point defects, and secondary hydrous mineral inclusions through an aperture of 10 µm for specimens > 40 µm thick. Doubly polished infrared (IR) plates can be prepared with thicknesses down to 4-8 µm, but measurement of small OH bands is currently limited by strong interference fringes for samples < 25 µm thick, precluding measurements of water within individual, finely recrystallized grains. By translating specimens under the 10 µm IR beam by steps of 10 to 50 µm, using a software-controlled x − y stage, spectra have been collected over specimen areas of nearly 4.5 mm 2 . This technique allowed us to separate and quantify broad OH bands due to fluid inclusions in quartz and OH bands due to micas and map their distributions in quartzites from the Moine Thrust (Scotland) and Main Central Thrust (Himalayas).Mylonitic quartzites deformed under greenschist facies conditions in the footwall to the Moine Thrust (MT) exhibit a large and variable 3400 cm −1 OH absorption band due to molecular water, and maps of water content corresponding to fluid inclusions show that inclusion densities correlate with deformation and recrystallization microstructures. Quartz grains of mylonitic orthogneisses and paragneisses deformed under amphibolite conditions in the hanging wall to the Main Central Thrust (MCT) exhibit smaller broad OH bands, and spectra are dominated by sharp bands at 3595 to 3379 cm −1 due to hydrogen point defects that appear to have uniform, equilibrium concentrations in the driest samples. The broad OH band at 3400 cm −1 in these rocks is much less common. The variable water concentrations of MT quartzites and lack of detectable water in highly sheared MCT mylonites challenge our understanding of quartz rheology. However, where water absorption bands can be detected and compared with deformation microstructures, OH concentration maps provide information on the histories of deformation and recovery, evidence for the introduction and loss of fluid inclusions, and water weakening processes.

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Section: Water Weakening In Nature?mentioning

confidence: 89%

Section: Ftirmentioning

confidence: 99%

Section: Wide Variations In Oh Contentmentioning

confidence: 99%

Section: Wide Variations In Oh Contentmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Synchrotron FTIR imaging of OH in quartz mylonites

et al. 2017

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Earthquakes as Precursors of Ductile Shear Zones in the Dry and Strong Lower Crust

Menegon¹,

Pennacchioni

Malaspina

et al. 2017

Geochem Geophys Geosyst

145

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The rheology and the conditions for viscous flow of the dry granulite facies lower crust are still poorly understood. Viscous shearing in the dry and strong lower crust commonly localizes in pseudotachylyte veins, but the deformation mechanisms responsible for the weakening and viscous shear localization in pseudotachylytes are yet to be explored. We investigated examples of pristine and mylonitized pseudotachylytes in anorthosites from Nusfjord (Lofoten, Norway). Mutual overprinting relationships indicate that pristine and mylonitized pseudotachylytes are coeval and resulted from the cyclical interplay between brittle and viscous deformation. The stable mineral assemblage in the mylonitized pseudotachylytes consists of plagioclase, amphibole, clinopyroxene, quartz, biotite, ± garnet ± K‐feldspar. Amphibole‐plagioclase geothermobarometry and thermodynamic modeling indicate that pristine and mylonitized pseudotachylytes formed at 650–750°C and 0.7–0.8 GPa. Thermodynamic modeling indicates that a limited amount of H2O infiltration (0.20–0.40 wt. %) was necessary to stabilize the mineral assemblage in the mylonite. Diffusion creep is identified as the main deformation mechanisms in the mylonitized pseudotachylytes based on the lack of crystallographic preferred orientation in plagioclase, the high degree of phase mixing, and the synkinematic nucleation of amphiboles in dilatant sites. Extrapolation of flow laws to natural conditions indicates that mylonitized pseudotachylytes are up to 3 orders of magnitude weaker than anorthosites deforming by dislocation creep, thus highlighting the fundamental role of lower crustal earthquakes as agents of weakening in strong granulites.

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The Rheological Evolution of Brittle‐Ductile Transition Rocks During the Earthquake Cycle: Evidence for a Ductile Precursor to Pseudotachylyte in an Extensional Fault System, South Mountains, Arizona

Stewart

Miranda

2017

JGR Solid Earth

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We investigate how the rheological evolution of shear zone rocks from beneath the brittle‐ductile transition (BDT) is affected by coeval ductile shear and pseudotachylyte development associated with seismicity during the earthquake cycle. We focus our study on footwall rocks of the South Mountains core complex, and we use electron backscatter diffraction (EBSD) analyses to examine how strain is localized in granodiorite mylonites both prior to and during pseudotachylyte development beneath the BDT. In mylonites that are host to pseudotachylytes, deformation is partitioned into quartz, where quartz exhibits crystallographic‐preferred orientation patterns and microstructures indicative of dynamic recrystallization during dislocation creep. Grain size reduction during dynamic recrystallization led to the onset of grain boundary sliding (GBS) accommodated by fluid‐assisted grain size‐sensitive (GSS) creep, localizing strain in quartz‐rich layers prior to pseudotachylyte development. The foliation‐parallel zones of GBS in the host mylonites, and the presence of GBS traits in polycrystalline quartz survivor clasts indicate that GBS zones were the ductile precursors to in situ pseudotachylyte generation. During pseudotachylyte development, strain was partitioned into the melt phase, and GSS deformation in the survivor clasts continued until crystallization of melt impeded flow, inducing pseudotachylyte development in other GBS zones. We interpret the coeval pseudotachylytes with ductile precursors as evidence of seismic events near the BDT. Grain size piezometry yields high differential stresses in both host mylonites (~160 MPa) and pseudotachylyte survivor clasts (> ~200 MPa), consistent with high stresses during interseismic and coseismic phases of the earthquake cycle, respectively.

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Water redistribution in experimentally deformed natural milky quartz single crystals—Implications for H₂O‐weakening processes

Cited by 53 publications

References 112 publications

Synchrotron FTIR imaging of OH in quartz mylonites

Synchrotron FTIR imaging of OH in quartz mylonites

Earthquakes as Precursors of Ductile Shear Zones in the Dry and Strong Lower Crust

The Rheological Evolution of Brittle‐Ductile Transition Rocks During the Earthquake Cycle: Evidence for a Ductile Precursor to Pseudotachylyte in an Extensional Fault System, South Mountains, Arizona

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Water redistribution in experimentally deformed natural milky quartz single crystals—Implications for H2O‐weakening processes

Cited by 53 publications

References 112 publications

Synchrotron FTIR imaging of OH in quartz mylonites

Synchrotron FTIR imaging of OH in quartz mylonites

Earthquakes as Precursors of Ductile Shear Zones in the Dry and Strong Lower Crust

The Rheological Evolution of Brittle‐Ductile Transition Rocks During the Earthquake Cycle: Evidence for a Ductile Precursor to Pseudotachylyte in an Extensional Fault System, South Mountains, Arizona

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Water redistribution in experimentally deformed natural milky quartz single crystals—Implications for H₂O‐weakening processes