Damage and Changes in Mechanical Properties of a Gabbro Thermally Loaded up to 1,000°C

Keshavarz, Mohammad Hossein; Pellet, Frédéric; Loret, Benjamin

doi:10.1007/s00024-010-0130-0

Cited by 114 publications

(59 citation statements)

References 24 publications

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“…We see a clear correlation of crack area per unit volume (Sv) to the observed compressional wave velocities ( Figure 8D) and interpret this to be attenuation of the compressional wave through the cracked intracrystalline and intercrystalline boundaries that are abundant in the andesite (e.g., Figures 3 and 4). Many authors (e.g., Vinciguerra et al 2005;Keshavarz et al 2010;Blake et al 2012; Heap et al 2014) have also shown that the elastic wave velocities can be highly attenuated by the presence of microcracks.…”

Section: Micromechanical Interpretationmentioning

confidence: 99%

“…The development of microcracks during uniaxial compression, and the coalescence of these cracks (newly formed and pre-existing), leads to the failure of the sample (Brace et al 1966;Bieniawski 1967). In samples that already show relatively high crack densities, less energy is required to coalesce existing cracks and thus they are inherently weaker (David et al 1999;Ferrero and Marini 2001;Keshavarz et al 2010). By utilizing AE monitoring during our UCS testing, we observe that fewer events occur during uniaxial compression in weaker samples than those with higher strength (Figure 10), indicating that there are far more pre-existing cracks in the weaker samples (Hardy 1981;Eberhardt et al 1998;Nicksiar and Martin 2012).…”

Section: Micromechanical Interpretationmentioning

confidence: 99%

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Physical property relationships of the Rotokawa Andesite, a significant geothermal reservoir rock in the Taupo Volcanic Zone, New Zealand

et al. 2014

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Background: Geothermal systems are commonly hosted in highly altered and fractured rock. As a result, the relationships between physical properties such as strength and permeability can be complex. Understanding such properties can assist in the optimal utilization of geothermal reservoirs. To resolve this issue, detailed laboratory studies on core samples from active geothermal reservoirs are required. This study details the results of the physical property investigations on Rotokawa Andesite which hosts a significant geothermal reservoir. Methods:We have characterized the microstructure (microfracture density), porosity, density, permeability, elastic wave velocities, and strength of core from the high-enthalpy Rotokawa Andesite geothermal reservoir under controlled laboratory conditions. We have built empirical relationships from our observations and also used a classical micromechanical model for brittle failure. Further, we compare our results to a Kozeny-Carman permeability model to better constrain the fluid flow behavior of the rocks. Results: We show that the strength, porosity, elastic moduli, and permeability are greatly influenced by pre-existing fracture occurrence within the andesite. Increasing porosity (or microfracture density) correlates well to a decreasing uniaxial compressive strength, increasing permeability, and a decreasing compressional wave velocity. Conclusions:Our results indicate that properties readily measurable by borehole geophysical logging (such as porosity and acoustic velocities) can be used to constrain more complex and pertinent properties such as strength and permeability. The relationships that we have provided can then be applied to further understand processes in the Rotokawa reservoir and other reservoirs worldwide.Keywords: Geothermal; Uniaxial compressive strength; Permeability; Physical properties; Elastic modulus; Microstructure BackgroundFractures on multiple scales are the dominant control on fluid flow in most geothermal systems worldwide. Geothermal environments are prone to variable heat fluxes, dynamic fluid flow regimes, and active tectonics which impact the physical and mechanical properties of the reservoir rocks in which they are hosted. The influence of such a dynamic environment can render the host rocks highly altered, fractured, and microstructurally complex. As a result, the empirical correlation of physical properties to

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Section: Micromechanical Interpretationmentioning

confidence: 99%

Section: Micromechanical Interpretationmentioning

confidence: 99%

Physical property relationships of the Rotokawa Andesite, a significant geothermal reservoir rock in the Taupo Volcanic Zone, New Zealand

et al. 2014

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“…Many experimental studies have been conducted on different rocks, [1][2][3][4][5][6][7][8][9][10][11][12][13][14] with an objective to observe and explain the behavior of physical and mechanical properties of these rocks under high temperature or after thermal treatment. All these experimental works are focus on sandstone [4][5][6][7], granite [1,[8][9][10], carbonates [2] and gabbro [11].…”

Section: Introductionmentioning

confidence: 99%

“…All these experimental works are focus on sandstone [4][5][6][7], granite [1,[8][9][10], carbonates [2] and gabbro [11]. However, few studies are interested on the gneiss rock microscopic analysis of thin section of the heated specimen.…”

Section: Introductionmentioning

confidence: 99%

Investigations of Thermal Damage on the Physical and Mechanical Properties of Gneiss Rock Specimen

NM¹

2017

J Powder Metall Min

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The effect of thermal damage on the physical and mechanical properties of gneiss has been experimentally investigated. The cylindrical samples prepared from this rock were gradually heated to a specific temperature level of 100, 200, 300, 400, 500, 700, and 900°C and gradually cooled down to room temperature without causing thermal cracking in order to investigate the effect of thermal treatment on physical properties and mechanical properties. The mechanical tests conducted on the sample were the Brazilian test and the uniaxial compressive test. Microscopic analyses from thin section were done to better understand the reasons for the mechanical behavior observed from the mechanical test results. Our study confirms that the thermal treatment reduces the strength of gneiss and increases its porosity. Moreover, it is found that above 600°C of heating, gneiss rock specimens can loss 80% of its original mechanical performances. This is due to a micro crack network connection and their propagation. However between 300 and 400°C we observe an increase in the strength of gneiss. Microscopic examination shows the abundance of feldspar and pyroxene minerals in the gneiss, which in turn show high mineralogical phase changes at 300-400°C compared to change at temperatures above 400°C.

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“…1, the stress-strain curve of this part is usually non-linear (concave). In particular, when a specimen experiences a high degree of thermal loading, the initial stress-strain curve will be strongly non-linear (Rosengren and Jaeger 1968, Homand-Etienne and Houpert 1989, Mahmutoglu 1998, Du et al 2004, Keshavarz et al 2010. Because the nonlinearity is associated with Fig.…”

Section: Introductionmentioning

confidence: 99%

A Phenomenological Model of Brittle Rocks under Uniaxial Compression

Peng

Cai

Liu

et al. 2015

IJGE

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A quantitative model was recently proposed by Peng et al (2015) to characterize the crack closure behavior of rocks. The model can simulate the initial nonlinearity of stress-strain curves in uniaxial and triaxial compressions. However, the crack propagation behavior near peak and in the postpeak deformation stage cannot be captured by the model. This paper extends the model to simulate the complete stress-strain curves of rocks under uniaxial compression. A phenomenological damage model, which uses a logistic function to describe the damage evolution, is adopted to model the pre-peak and post-peak deformation stages beyond the crack closure stage. Combining the crack closure model and the damage model yields a new phenomenological model. A uniform continuity condition is used to ensure that the stress-strain curve is smooth and continuous at the junction point of the crack closure model and the damage model. The proposed model has four model parameters, which can be calibrated using laboratory test data. The uniaxial compression tests of the Carrara marble under different heating cycles are simulated to verify the proposed model. The simulated stress-strain curves agree well with the test data, from initial crack closure to near peak and post peak, suggesting that the model can be used for simulating the entire deformation stage of brittle rocks with different degrees of initial microcrack damage.

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Damage and Changes in Mechanical Properties of a Gabbro Thermally Loaded up to 1,000°C

Cited by 114 publications

References 24 publications

Physical property relationships of the Rotokawa Andesite, a significant geothermal reservoir rock in the Taupo Volcanic Zone, New Zealand

Physical property relationships of the Rotokawa Andesite, a significant geothermal reservoir rock in the Taupo Volcanic Zone, New Zealand

Investigations of Thermal Damage on the Physical and Mechanical Properties of Gneiss Rock Specimen

A Phenomenological Model of Brittle Rocks under Uniaxial Compression

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