Thermo-mechanical behavior of a granodiorite from the Liquiñe fractured geothermal system (39°S) in the Southern Volcanic Zone of the Andes

• Published in: Geothermics Vol. 87; p. 101828
• Main Authors: Sepúlveda, J., Arancibia, G., Molina, E., Gilbert, J.P., Duda, M., Browning, J., Roquer, T., Morata, D., Ahrens, B., Bracke, R.
• Format: Journal Article
• Language: English
• Published: Oxford Elsevier Ltd 01.09.2020; Elsevier Science Ltd
• Subjects: Andean Southern Volcanic Zone; Computational fluid dynamics; Cracking (fracturing); Crystalline rock; Damage; Faults; Fractured geothermal system; Fractures; Geothermal power; Hydro-mechanical properties; Low temperature; Mechanical loading; Mechanical properties; Mechanical tests; Microfracture; Permeability; Physical properties; Repeated loading; Reservoirs; Rocks; Room temperature; Stiffness; Temperature; Thermo-mechanical properties; Thermomechanical properties; Triaxial loads; X ray microtomography; Andean Southern Volcanic Zone; Fractured geothermal system; Crystalline rock; Hydro-mechanical properties; Thermo-mechanical properties
• ISSN: 0375-6505; 1879-3576
• DOI: 10.1016/j.geothermics.2020.101828

[Display omitted] •Calculate the dynamic and static parameters from uniaxial and triaxial test after different heat treatments (<300 °C).•Estimate the elastic parameter from thermo-triaxial test at temperatures below 100 °C.•Compare quantitatively the calculated parameters to estimate the thermal stress in the granodiorite.•Numerical modelling from X-ray images to estimate the permeability of fractures generated in the triaxial tests. Fractures and faults in granitic rocks play an important role in geothermal systems because they permit the circulation of hot fluids. However, the thermo-hydro-mechanical behavior of granitic rocks has predominantly been studied at temperatures exceeding 300 °C but many geothermal systems experience temperatures much lower than this. The aim of this study was to evaluate how the depth, temperature, and amount and rate of mechanical loading associated conditions, that are realistic in low temperature geothermal system, influence the physical properties of geothermal reservoir hosting rock. We carried out both room temperature and low temperature thermo-mechanical tests on a granodiorite sample from the Liquiñe area, Chile, and performed post-experimental X-ray microtomography analysis to numerically estimate the permeability of the generated fractures. The results showed that both rock strength and rock stiffness decreased with increments of temperature treatment related to the development of thermal crack damage at temperatures > 150 °C and through the development of sub-critical cracking at constant temperatures between 50–75 °C. Slowest deformed samples also exhibited lower strengths, attributed to the development of sub-critical cracking. The cyclic triaxial loading test indicated that significant mechanical fracture damage was only initiated above 80% of the peak stress regardless of the number of repeated loading cycles at lower stresses. Low-temperature treatment appears to be a conditioning factor, but not the dominant factor in controlling the physical properties of reservoir hosting rocks. Our findings indicate that thermal crack damage is likely important for developing microfracture related permeability at depths between around 2–6 km where the temperature is sufficiently high to induce thermal cracking. At shallower depths, such was previously estimated the reservoir of Liquiñe, thermal crack damage is only generated adjacent to fractures that remain open and circulate the hot fluids but sub-critical cracking over time reduces the strength of rocks in lower temperature regimes. These processes combined to produce a geothermal reservoir in Liquiñe which likely first required the presence of a highly fractured fault zone.