α/β phase transition in quartz monitored using acoustic emissions

Glover, Paul; Baud, Patrick; Darot, M.; Meredith, P. G.; Boon, S. A.; LeRavalec, M.; Zoussi, S.; Reuschlé, Thierry

doi:10.1111/j.1365-246x.1995.tb01852.x

Cited by 266 publications

(100 citation statements)

References 14 publications

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“…We can conclude that (1) mineralogical changes (and in particular decarbonation) and phase transitions give raise to the most significant changes in the elastic moduli of rocks: e.g., decarbonation (in the case of carbonates, this study), the α-β quartz transition (in granites and sandstones, see Glover et al, 1995), and the loss of water from zeolites (in pyroclastic deposits, see Heap et al, 2012). In the absence of chemical alteration, and when the rocks already contain an extensive thermal microcrack network [the case for the basalt of Heap et al (2009) and the andesite of Petrakova et al, 2012], no changes were observed.…”

Section: Accepted M Manuscriptmentioning

confidence: 69%

Thermal weakening of the carbonate basement under Mt. Etna volcano (Italy): Implications for volcano instability

Heap

Mollo

Vinciguerra

et al. 2013

Journal of Volcanology and Geothermal Research

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The physical integrity of a sub-volcanic basement is crucial in controlling the stability of a volcanic edifice. For many volcanoes, this basement can comprise thick sequences of carbonates that are prone to significant thermally-induced alteration. These debilitating thermal reactions, facilitated by heat from proximal magma storage volumes, promote the weakening of the rock mass and likely therefore encourage edifice instability. Such instability can result in slow, gravitational spreading and episodic to continuous slippage of unstable flanks, and may also facilitate catastrophic flank collapse. Understanding the propensity of a particular sub-volcanic basement to such instability requires a detailed understanding of the influence of high temperatures on the chemical, physical, and mechanical properties of the rocks involved. The juxtaposition of a thick carbonate substratum and magmatic heat sources makes Mt. Etna volcano an ideal candidate for our study. We investigated experimentally the effect of temperature on two carbonate rocks that have been chosen to represent the deep, heterogeneous sedimentary substratum under Mt. Etna volcano. This study has demonstrated that thermalstressing resulted in a progressive and significant change in the physical properties of the two rocks. Porosity, wet (i.e., water-saturated) dynamic Poisson's ratio and wet Vp/Vs ratio all increased, whilst P-and S-wave velocities, bulk sample density, dynamic and static Young's modulus, dry Vp/Vs ratio, and dry dynamic Poisson's ratio all decreased. At temperatures of 800 °C, the carbonate in these rocks completely dissociated, resulting in a total mass loss of about 45% and the release of about 44 wt.% of CO 2 . Uniaxial deformation experiments showed that high in-situ temperatures (> 500°C) significantly reduced the strength of the carbonates and altered their deformation behaviour. Above 500 °C the rocks deformed in a ductile manner and A C C E P T E D M A N U S C R I P T ACCEPTED MANUSCRIPTthe output of acoustic emissions was greatly reduced. We speculate that thermally-induced weakening and the ductile behaviour of the carbonate substratum could be a key factor in explaining the large-scale deformation observed at Mt. Etna volcano. Our findings are consistent with several field observations at Mt. Etna volcano and can quantitatively support the interpretation of (1) the irregularly low seismic velocity zones present within the sub-volcanic sedimentary basement, (2) the anomalously high CO 2 degassing observed, (3) the anomalously high Vp/Vs ratios and the rapid migration of fluids, and (4) the increasing instability of volcanic edifices in the lifespan of a magmatic system. We speculate that carbonate sub-volcanic basement may emerge as one of the decisive fundamentals in controlling volcanic stability.

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Section: Accepted M Manuscriptmentioning

confidence: 69%

Thermal weakening of the carbonate basement under Mt. Etna volcano (Italy): Implications for volcano instability

Heap

Mollo

Vinciguerra

et al. 2013

Journal of Volcanology and Geothermal Research

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“…should not be expected between 100 and 200 °C, but become more significant above 400 or 500 °C (Tian et al 2012). Indeed, thermal cracking experiments have shown that the greatest changes are likely to be achieved once the temperature has exceeded 573 °C, i.e., the α/β transition of quartz (Glover et al 1995). Li et al (2011) investigated the change in the longitudinal wave velocity and mechanical behavior of sandstone after different high-temperature treatments using triaxial unloading experiments.…”

Section: Discussionmentioning

confidence: 97%

“…Many experimental investigations have demonstrated that high temperature significantly affects the physical properties of sandstones (Heuze 1983;Glover et al 1995;Chopra 1997;Zhang et al 2001;Tang et al 2011;Zhao et al 2012). Analytical and numerical modeling of thermomechanical processes in sandstones have shown that variations in rock physical properties (such as bulk density, porosity, compressional wave velocity, etc.)…”

Section: Discussionmentioning

confidence: 99%

Strength Failure and Crack Evolution Behavior of Rock Materials Containing Pre-existing Fissures

Yang¹

2015

Springer Environmental Science and Engineering

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“…Temperature equilibrium in the sample was reached after approximately 75 minutes, and the thermal gradient along the sample was less than 1°C/cm. Experiments were performed at temperatures from 20°to 75°C because previous studies suggest (1) that thermal cracking in many crustal rocks commences around 100°C [Glover et al, 1995], so is likely to be minimised or precluded over this range, and (2) that this range is sufficient to significantly influence the rate of stress corrosion [Meredith and Atkinson, 1983].…”

Section: Experimental Materials and Methodologymentioning

confidence: 99%

Influence of temperature on brittle creep in sandstones

Heap¹,

Baud²,

Meredith³

2009

Geophysical Research Letters

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151

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[1] The characterization of time-dependent brittle creep, promoted by chemically active pore fluids, is fundamental to our understanding of the long-term evolution and dynamics of the Earth's crust. Here we report results from a study of the influence of temperature on both short-term strength and time-dependent brittle creep in three sandstones under triaxial stress conditions. We show that an increase in temperature from 20°to 75°C significantly enhances stress corrosion cracking in all three sandstones, leading to (1) a systematic reduction in strength during constant strain rate experiments and (2) an increase by several orders of magnitude in brittle creep strain rates during stress-stepping creep experiments. We also show that a conventional creep experiment performed at 75°C exhibits a qualitatively similar three-stage brittle creep curve as that observed at ambient temperature. Extrapolation of our results suggests that temperature is likely to be the dominant influence on the evolution of creep strain rate with depth in the shallow crust.

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α/β phase transition in quartz monitored using acoustic emissions

Cited by 266 publications

References 14 publications

Thermal weakening of the carbonate basement under Mt. Etna volcano (Italy): Implications for volcano instability

Thermal weakening of the carbonate basement under Mt. Etna volcano (Italy): Implications for volcano instability

Strength Failure and Crack Evolution Behavior of Rock Materials Containing Pre-existing Fissures

Influence of temperature on brittle creep in sandstones

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