The microstructural response of quartz and feldspar under shock loading at variable temperatures

Huffman, Alan R.; Brown, J. M.; Carter, Neville L.; Reimold, W. U.

doi:10.1029/93jb01425

Cited by 47 publications

(55 citation statements)

References 41 publications

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“…This particular rock type was chosen because it occurs, naturally shock deformed, in the central uplift of the Vredefort impact structure, the Vredefort dome. The samples used in this study and previously described by Reimold and Hörz (1986), Huffman et al (1993), and Huffman and Reimold (1996) show virtually no accessory phases (sericite <1 vol%); evidence of tectonic deformation was restricted to occasional weak subgrain development and rare tectonic lamellae. The samples were cut into plates of about 1 mm thickness and embedded in densitymatching epoxy material.…”

Section: Samples and Experimental Proceduressupporting

confidence: 56%

“…These include the investigation of the Raman properties of coesite from the Vredefort dome, South Africa (Halvorson and McHone 1992), coesite in suevite from the Chicxulub impact structure, Mexico Ostroumov et al 2002), natural and synthetic coesite (Boyer et al 1985), the coesite-stishovite transition (e.g., Serghiou et al 1995), the densification behavior of silica glasses in shock experiments (Okuno et al 1999), and tektites and impact glasses (Faulques et al 2001) The pre-shock temperature of the target rock also influences the formation and crystallographic orientation of PDFs. Reimold (1988), Huffman et al (1993), and Huffman and Reimold (1996) presented the results of shock experiments with quartzite and granite at room temperature (25°C) and preheated to 450°C and 750°C. They noticed a distinct difference in the relative abundances of the {1013} and {1012} orientations and a large difference in the number of sets of PDFs per grain.…”

Section: Introductionmentioning

confidence: 99%

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Scanning electron microscopy, cathodoluminescence, and Raman spectroscopy of experimentally shock‐metamorphosed quartzite

Gucsik

Koeberl

Brandstätter

et al. 2003

Meteorit & Planetary Scien

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Abstract-We studied unshocked and experimentally (at 12, 25, and 28 GPa, with 25, 100, 450, and 750°C pre-shock temperatures) shock-metamorphosed Hospital Hill quartzite from South Africa using cathodoluminescence (CL) images and spectroscopy and Raman spectroscopy to document systematic pressure or temperature-related effects that could be used in shock barometry. In general, CL images of all samples show CL-bright luminescent patchy areas and bands in otherwise nonluminescent quartz, as well as CL-dark irregular fractures. Fluid inclusions appear dominant in CL images of the 25 GPa sample shocked at 750°C and of the 28 GPa sample shocked at 450°C. Only the optical image of our 28 GPa sample shocked at 25°C exhibits distinct planar deformation features (PDFs). Cathodoluminescence spectra of unshocked and experimentally shocked samples show broad bands in the near-ultraviolet range and the visible light range at all shock stages, indicating the presence of defect centers on, e.g., SiO 4 groups. No systematic change in the appearance of the CL images was obvious, but the CL spectra do show changes between the shock stages. The Raman spectra are characteristic for quartz in the unshocked and 12 GPa samples. In the 25 and 28 GPa samples, broad bands indicate the presence of glassy SiO 2 , while high-pressure polymorphs are not detected. Apparently, some of the CL and Raman spectral properties can be used in shock barometry.

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Section: Samples and Experimental Proceduressupporting

confidence: 56%

Section: Introductionmentioning

confidence: 99%

Scanning electron microscopy, cathodoluminescence, and Raman spectroscopy of experimentally shock‐metamorphosed quartzite

Gucsik

Koeberl

Brandstätter

et al. 2003

Meteorit & Planetary Scien

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“…and rocks are probably due to the major differences in the initial Note that the experiments employed naturally shock-processed propcrtics of Kernouvd and the analogue materials. Shock experiments with hcatcd samples were reported previously for quartz (Langenhorst, 1093;Huffman et al, 1993;Langenhorst and Dcutsch, 1994) and plagioclase (I Iuffman et al., 1993). For the samples preheated to 920 K (high-temperature experiments), the olivine, orthopyroxene, and oligoclase in Kernouve display the same pressure-dependent sequence of shock features as in the low-temperature experiments.…”

Section: Discussion Pressure Calibration Of Shock Effects In Olivinementioning

confidence: 81%

Shock experiments with the H6 chondrite Kernouvé: Pressure calibration of microscopic shock effects

Schmitt

2000

Meteorit & Planetary Scien

101

113

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Abstract-Shock-recovery experiments were carried out on samples of the H6 chondrite Kernouve at shock pressures of 10, 15, 20, 25, 30, 35, 45, and 60 GPa and preheating temperatures of 293 K (low-temperature experiments) and 920 K (high-temperature experiments). Using a calculated equation of state of Kernouve, pressure-pulse durations of 0.3 to 1.2 ,us were estimated. The shocked samples were investigated by optical microscopy to calibrate the various shock effects in olivine, orthopyroxene, oligoclase, and troilite.The following pressure calibration is proposed for silicates: (1) undulatory extinction of olivine <15 GPa; (2) weak mosaicism of olivine from 10-15 GPa to 20-25 GPa; (3) onset of strong mosaicism of olivine at 20-25 GPa; (4) transformation of oligoclase to diaplectic glass completed at 25-30 GPa (low-temperature experiments) and at 20-25 GPa (high-temperature experiments); ( 5 ) onset of weak mosaicism in orthopyroxene at 30-35 GPa (low-temperature experiments) and at 25-30 GPa (high-temperature experiments); and (6) recrystallization or melting of olivine starting at 4 5 4 0 GPa (low-temperature experiments) and at 3 5 4 5 GPa (high-temperature experiments), and completed above 45-60 GPa in the high-temperature experiments.Troilite displays distinct differences between the samples shocked at low and high temperatures. In the low-temperature experiments, the following effects can be observed in troilite: (1) undulatory extinction up to 25 GPa, (2) twinning up to 45 GPa, (3) partial recrystallization from 30 to 60 GPa, and (4) complete recrystallization >35 GPa; whereas in the high-temperature experiments, troilite shows (1) complete recrystallization from 10 up to 45 GPa and (2) melting and crystallization above 45 GPa.Localized shock-induced melting is observed in samples shocked to pressures >15 GPa in the hightemperature experiments and >30 GPa for the low-temperature experiments in the form of FeNi metal and troilite melt injections and intergrowths and as pockets and veins of whole-rock melt. Obviously, the onset and abundance of shock-induced localized melting strongly depends on the initial temperature of the sample.

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“…The grain size is uniform with a mean diameter of about 300 lm and a very low porosity ((1%) (BRACE, 1965;HUFFMAN et al, 1993). The Young's modulus is E o ¼ 70 GPa and Poisson's ratio is m = 0.25.…”

Section: Testing Case 1 Using Deformation Data For Westerly Granitementioning

confidence: 99%

The Micromechanics of Westerley Granite at Large Compressive Loads

Bhat

Sammis

Rosakis³

2011

Pure Appl. Geophys.

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Abstract-The micromechanical damage mechanics formulated by ASHBY and SAMMIS (Pure Appl Geophys 133(3) 1990) has been shown to give an adequate description of the triaxial failure surface for a wide variety of rocks at low confining pressure. However, it does not produce the large negative curvature in the failure surface observed in Westerly granite at high confining pressure. We show that this discrepancy between theory and data is not caused by the two most basic simplifying assumptions in the damage model: (1) that all the initial flaws are the same size or (2) that they all have the same orientation relative to the largest compressive stress. We also show that the stress-strain curve calculated from the strain energy density significantly underestimates the nonlinear strain near failure in Westerly granite. Both the observed curvature in the failure surface and the nonlinear strain at failure observed in Westerly granite can be quantitatively fit using a simple bi-mineral model in which the feldspar grains have a lower flow stress than do the quartz grains. The conclusion is that nonlinearity in the failure surface and stress-strain curves observed in triaxial experiments on Westerly granite at low loading rates is probably due to low-temperature dislocation flow and not simplifying assumptions in the damage mechanics. The important implication is that discrepancies between experiment and theory should decrease with increased loading rates, and therefore, the micromechanical damage mechanics, as formulated, can be expected to give an adequate description of high strain-rate phenomena like earthquake rupture, underground explosions, and meteorite impact.

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The microstructural response of quartz and feldspar under shock loading at variable temperatures

Cited by 47 publications

References 41 publications

Scanning electron microscopy, cathodoluminescence, and Raman spectroscopy of experimentally shock‐metamorphosed quartzite

Scanning electron microscopy, cathodoluminescence, and Raman spectroscopy of experimentally shock‐metamorphosed quartzite

Shock experiments with the H6 chondrite Kernouvé: Pressure calibration of microscopic shock effects

The Micromechanics of Westerley Granite at Large Compressive Loads

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