Abstract
The effect of high temperature on engineering properties of rocks has recently become an important topic for geotechnical engineering applications due to the development in geothermal energy extraction, underground coal gasification, disposal of nuclear waste and deep mining applications. This study aims to investigate the engineering properties of four rocks heated at high temperatures and to identify the corresponding mineralogical changes. Two types of sandstone (Beaudesert sandstone and Jimboomba sandstone), basalt and argillite were subjected to a range of temperatures from 25 to 800 °C and their properties such as porosity and point load index were studied through a series of laboratory experiments. The physical and mineralogical alteration of the heated rock specimens were also investigated to better understand the thermally induced processes that occurred in each rock type using the X-Ray Diffraction, Thermogravimetry (TG), Differential Scanning Calorimetry (DSC) and Derivative Thermogravimetry (DTG) techniques. The obtained data indicated the important role of mineral composition in the thermal behaviour of the studied rocks. Noticeable changes in the mineral compositions at the threshold temperature were observed for each rock type. This behaviour was confirmed with TG/DSC/DTG analysis. This temperature-related process resulted in the formation of cracks, an increase in porosity and a decrease in strength. However, the effects of high temperatures on engineering properties were found to be different in the two sandstone types. While Beaudesert sandstone underwent significant weakening at high temperatures, only a slight change in the strength of Jimboomba sandstone was recorded. The threshold temperatures were identified as 400 °C, 400 °C, 500 °C and 300 °C, for the tested Beaudesert sandstone, Jimboomba sandstone, basalt and argillite samples, respectively. The critical temperatures (obtained using a damage coefficient) were found as 570 °C for both Beaudesert sandstone and basalt, and 440 °C for argillite. Analysis of the laboratory data revealed the difference between the threshold temperatures and the critical temperatures. It is recommended to use both threshold temperature and critical temperature parameters to provide more accurate estimations of the temperature range at which rock undergoes significant changes.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Availability of data and material
Date and material will be made available on request.
References
Abdulagaov I, Abdulagatova Z, Kallaev S, Omarov Z (2019) Heat-capacity measurements of sandstone at high temperatures. Geomech Geophys Geo Energy Geo Resour 5(1):65–85
Becattini V, Motmans T, Zappone A, Madonna C, Haselbacher A, Steinfeld A (2017) Experimental investigation of the thermal and mechanical stability of rocks for high-temperature thermal-energy storage. Appl Energy 203:373–389
Brotons V, Tomás R, Ivorra S, Alarcón J (2013) Temperature influence on the physical and mechanical properties of a porous rock: San Julian’s calcarenite. Eng Geol 167:117–127
Chaki S, Takarli M, Agbodjan W (2008) Influence of thermal damage on physical properties of a granite rock: porosity, permeability and ultrasonic wave evolutions. Constr Build Mater 22(7):1456–1461
Darot M, Reuschlé T (2000) Acoustic wave velocity and permeability evolution during pressure cycles on a thermally cracked granite. Int J Rock Mech Min Sci 37(7):1019–1026
Delle Piane C, Arena A, Sarout J, Esteban L, Cazes E (2015) Micro-crack enhanced permeability in tight rocks: an experimental and microstructural study. Tectonophysics 665:149–156
Ding QL, Ju F, Song SB, Yu BY, Ma D (2016) An experimental study of fractured sandstone permeability after high-temperature treatment under different confining pressures. J Nat Gas Sci Eng 34:55–63
Dmitriyev AP, Kuzyayev LS, Protasov YI, Yamsbcbikov VS (1969) Physical properties of rocks at high temperatures. Nedra Press, Moscow
Dong Z, Sun Q, Ranjith PG (2019) Surface properties of grayish-yellow sandstone after thermal shock. Environ Earth Sci 78(14):420
Duclos R, Paquet J (1991) High-temperature behaviour of basalts—role of temperature and strain rate on compressive strength and Kic toughness of partially glassy basalts at atmospheric pressure. Int J Rock Mech Min Sci Geomech Abstr 28:71–76
Ersoy H, Kolaylı H, Karahan M, Karahan HH, Sünnetci MO (2017) Effect of thermal damage on mineralogical and strength properties of basic volcanic rocks exposed to high temperatures. Bull Eng Geol Environ 78(3):1515–1525
Fang X, Xu J, Wang P (2018) Compressive failure characteristics of yellow sandstone subjected to the coupling effects of chemical corrosion and repeated freezing and thawing. Eng Geol 233:160–171
Faoro I, Elsworth D, Candela T (2016) Evolution of the transport properties of fractures subject to thermally and mechanically activated mineral alteration and redistribution. Geofluids 16(3):396–407
Frolova J, Ladygin V, Rychagov S, Zukhubaya D (2014) Effects of hydrothermal alterations on physical and mechanical properties of rocks in the Kuril–Kamchatka Island Arc. Eng Geol 183:80–95
Gialanella S, Girardi F, Ischia G, Lonardelli I, Mattarelli M, Montagna M (2010) On the goethite to hematite phase transformation. J Therm Anal Calorim 102(3):867–873
Glover P, Baud P, Darot M et al (1995) α/β phase transition in quartz monitored using acoustic emissions. Geophys J Int 120(3):775–782
Gratchev I, Kim DH (2016) On the reliability of the strength retention ratio for estimating the strength of weathered rocks. Eng Geol 201:1–5
Gratchev I, Shokouhi A, Kim DH, Stead D, Wolter A (2013) Assessment of rock slope stability using remote sensing technique in the Gold Coast area, Australia. In: Paper presented at the 18th Southeast Asian geotechnical & inaugural AGSSEA conference
Gratchev I, Pathiranagei SV, Kim DH (2019) Strength properties of fresh and weathered rocks subjected to wetting–drying cycles. Geomech Geophys Geo-Energy Geo-Resour 5(3):211–221
Hager I (2014) Sandstone colour change due to the high temperature exposure. In: Paper presented at the advanced materials research
Hajpál M, Török A (2004) Mineralogical and colour changes of quartz sandstones by heat. Environ Geol 46(3–4):311–322
Hassanzadegan A, Blöcher G, Milsch H, Urpi L, Zimmermann G (2014) The effects of temperature and pressure on the porosity evolution of Flechtinger sandstone. Rock Mech Rock Eng 47(2):421–434
Heuze F (1983) High-temperature mechanical, physical and thermal properties of granitic rocks—a review. Int J Rock Mech Min Sci Geomech Abstr 20(1):3–10
Hu J, Sun Q, Pan X (2018) Variation of mechanical properties of granite after high-temperature treatment. Arab J Geosci 11(2):43
Jiang G, Zuo J, Li L, Ma T, Wei X (2018) The evolution of cracks in Maluanshan granite subjected to different temperature processing. Rock Mech Rock Eng 51(6):1683–1695
Keppert M, Fořt J, Trník A, Koňáková D, Vejmelková E, Pokorný J, Černý R (2017) Behavior of sandstones under heat treatment. Int J Thermophys 38(4):60
Keshavarz M, Pellet F, Loret B (2010) Damage and changes in mechanical properties of a gabbro thermally loaded up to 1000 °C. Pure Appl Geophys 167(12):1511–1523
Kong B, Wang E, Li Z, Wang X, Liu X, Li N, Yang Y (2016) Electromagnetic radiation characteristics and mechanical properties of deformed and fractured sandstone after high temperature treatment. Eng Geol 209:82–92
Kong L, Ostadhassan M, Hou X, Mann M, Li C (2019) Microstructure characteristics and fractal analysis of 3D-printed sandstone using micro-CT and SEM-EDS. J Petrol Sci Eng 175:1039–1048
Kumari W, Ranjith P, Perera M, Li X, Li L, Chen B, De Silva V (2018) Hydraulic fracturing under high temperature and pressure conditions with micro CT applications: geothermal energy from hot dry rocks. Fuel 230:138–154
Kumari W, Beaumont D, Ranjith P, Perera M, Isaka BA, Khandelwal M (2019) An experimental study on tensile characteristics of granite rocks exposed to different high-temperature treatments. Geomech Geophys Geo-Energy Geo-Resour 5(1):47–64
Lan J (2009) A study of the mechanical properties of sandstone after cyclic thermal action. M.Sc. thesis, National Cheng Kung University, Taiwan, 4548
Li M, Mao X, Cao L, Pu H, Mao R, Lu A (2016) Effects of thermal treatment on the dynamic mechanical properties of coal measures sandstone. Rock Mech Rock Eng 49(9):3525–3539
Liu S, Xu J (2015) An experimental study on the physico-mechanical properties of two post-high-temperature rocks. Eng Geol 185:63–70
Liu X, Zhang C, Yuan S, Fityus S, Sloan SW, Buzzi O (2016) Effect of high temperature on mineralogy, microstructure, shear stiffness and tensile strength of two Australian mudstones. Rock Mech Rock Eng 49(9):3513–3524
Liu J, Li B, Tian W, Wu X (2018) Investigating and predicting permeability variation in thermally cracked dry rocks. Int J Rock Mech Min Sci 103:77–88
Liu Z, Shao J, Xie S, Conil N, Talandier J (2019) Mechanical behavior of claystone in lateral decompression test and thermal effect. Rock Mech Rock Eng 52(2):321–334
Lu Y, Wang L, Sun X, Wang J (2017) Experimental study of the influence of water and temperature on the mechanical behavior of mudstone and sandstone. Bull Eng Geol Environ 76(2):645–660
Mahanta B, Vishal V, Ranjith P, Singh T (2020) An insight into pore-network models of high-temperature heat-treated sandstones using computed tomography. J Nat Gas Sci Eng 77:103227
Maruvanchery V, Kim E (2020) Effects of a high temperature (500 °C) on the fracture processes in calcite-cemented sandstone along bedding-plane orientations. Rock Mech Rock Eng 53:955–966
McCabe S, Smith B, Warke P (2010) Exploitation of inherited weakness in fire-damaged building sandstone: the ‘fatiguing’of ‘shocked’stone. Eng Geol 115(3–4):217–225
Meng T, Liu R, Meng X, Zhang D, Hu Y (2019) Evolution of the permeability and pore structure of transversely isotropic calcareous sediments subjected to triaxial pressure and high temperature. Eng Geol 253:27–35
Ozguven A, Ozcelik Y (2014) Effects of high temperature on physico-mechanical properties of Turkish natural building stones. Eng Geol 183:127–136
Ranjith P, Viete DR, Chen BJ, Perera MSA (2012) Transformation plasticity and the effect of temperature on the mechanical behaviour of Hawkesbury sandstone at atmospheric pressure. Eng Geol 151:120–127
Rao Q, Wang Z, Xie H, Xie Q (2007) Experimental study of mechanical properties of sandstone at high temperature. J Cent South Univ T 14(1):478–483
Rathnaweera T, Ranjith P, Gu X et al (2018) Experimental investigation of thermomechanical behaviour of clay-rich sandstone at extreme temperatures followed by cooling treatments. Int J Rock Mech Min Sci 107:208–223
Rong G, Peng J, Yao M, Jiang Q, Wong LNY (2018) Effects of specimen size and thermal-damage on physical and mechanical behavior of a fine-grained marble. Eng Geol 232:46–55
Shen YJ, Zhang YL, Gao F, Yang GS, Lai XP (2018) Influence of temperature on the microstructure deterioration of sandstone. Energies 11(7):1753
Sirdesai N, Mahanta B, Ranjith P, Singh T (2019) Effects of thermal treatment on physico-morphological properties of Indian fine-grained sandstone. Bull Eng Geol Environ 78(2):883–897
Somerton WH (1992) Thermal properties and temperature-related behavior of rock/fluid systems. Amsterdam, Netherlands
Standards Australia (2005) Methods of testing rocks for engineering purposes: rock porosity and density (AS 4133.2.1.2-2005). Retrieved from SAI Global
Standards Australia (2007) Methods of testing rocks for engineering purposes rock strength tests: determination of point load strength index (AS 4133.4.1-2007). Retrieved from SAI Global
Sun Q, Zhang W, Su T, Zhu S (2016) Variation of wave velocity and porosity of sandstone after high temperature heating. Acta Geophys 64(3):633–648
Sygała A, Bukowska M (2019) Identification of temperature effect on post-critical geomechanical properties of loaded sandstones. Arab J Geosci 12(10):315
Takarli M, Prince W, Siddique R (2008) Damage in granite under heating/cooling cycles and water freeze–thaw condition. Int J Rock Mech Min Sci 45(7):1164–1175
Tang Y, Okubo S, Xu J, Peng S (2019a) Progressive failure behaviors and crack evolution of rocks under triaxial compression by 3D digital image correlation. Eng Geol 249:172–185
Tang ZC, Sun M, Peng J (2019b) Influence of high temperature duration on physical, thermal and mechanical properties of a fine-grained marble. Appl Therm Eng 156:34–50
Tian H, Kempka T, Yu S, Ziegler M (2016) Mechanical properties of sandstones exposed to high temperature. Rock Mech Rock Eng 49(1):321–327
Tian H, Mei G, Jiang GS, Qin Y (2017) High-temperature influence on mechanical properties of diorite. Rock Mech Rock Eng 50(6):1661–1666
Vagnon F, Colombero C, Colombo F, Comina C, Ferrero AM, Mandrone G, Vinciguerra SC (2019) Effects of thermal treatment on physical and mechanical properties of Valdieri Marble-NW Italy. Int J Rock Mech Min Sci 116:75–86
Wang F, Frühwirt T, Konietzky H, Zhu Q (2019) Thermo-mechanical behaviour of granite during high-speed heating. Eng Geol 260:105258
Wang D, Zhang P, Wei J, Yu C (2020) The seepage properties and permeability enhancement mechanism in coal under temperature shocks during unloading confining pressures. J Nat Gas Sci Eng 77:103242
Wawersik WR, Hannum DW (1980) Mechanical behavior of New Mexico rock salt in triaxial compression up to 200 °C. J Geophys Res Solid Earth 85(B2):891–900
Wu Z, Qin BD, Chen LJ, Luo YJ (2005) Experimental study on mechanical character of sandstone of the upper plank of coal bed under high temperature. Chin J Rock Mech Eng 24(11):1863–1867
Wu Q, Weng L, Zhao Y, Guo B, Luo T (2019a) On the tensile mechanical characteristics of fine-grained granite after heating/cooling treatments with different cooling rates. Eng Geol 253:94–110
Wu X, Huang Z, Cheng Z, Zhang S, Song H, Zhao X (2019b) Effects of cyclic heating and LN2-cooling on the physical and mechanical properties of granite. Appl Therm Eng 156:99–110
Xiong L, Chen H, Li T, Zhang Y (2018) Experimental study on the uniaxial compressive strength of artificial jointed rock mass specimen after high temperatures. Geomech Geophys Geo Energy Geo Resour 4(3):201–213
Xu Y, Sun D, Zeng Z, Lv H (2019) Effect of aging on thermal conductivity of compacted bentonites. Eng Geol 253:55–63
Yang SQ, Xu P, Li YB, Huang YH (2017) Experimental investigation on triaxial mechanical and permeability behavior of sandstone after exposure to different high temperature treatments. Geothermics 69:93–109
Yang SQ, Yin PF, Huang YH, Cheng JL (2019) Strength, deformability and X-ray micro-CT observations of transversely isotropic composite rock under different confining pressures. Eng Fract Mech 214:1–20
Yao M, Rong G, Zhou C, Peng J (2016) Effects of thermal damage and confining pressure on the mechanical properties of coarse marble. Rock Mech Rock Eng 49(6):2043–2054
Zhang R-R, Yuan P (2019) Effect of hydrothermal coupling on physical and dynamic mechanical properties of sandstone. Adv Civ Eng 2019:1–14
Zhang Q, Zhao J (2013) Determination of mechanical properties and full-field strain measurements of rock material under dynamic loads. Int J Rock Mech Min Sci 60:423–439
Zhang Y, Zhao GF (2020) A global review of deep geothermal energy exploration: from a view of rock mechanics and engineering. Geomech Geophys Geo Energy Geo Resour 6(1):4
Zhang L, Mao X, Lu A (2009) Experimental study on the mechanical properties of rocks at high temperature. Sci China Technol Sci 52(3):641–646
Zhang Y, Sun Q, Geng J (2017) Microstructural characterization of limestone exposed to heat with XRD, SEM and TG-DSC. Mater Charact 134:285–295
Zhang F, Zhao J, Hu D, Skoczylas F, Shao J (2018a) Laboratory investigation on physical and mechanical properties of granite after heating and water-cooling treatment. Rock Mech Rock Eng 51(3):677–694
Zhang W, Sun Q, Zhang Y, Xue L, Kong F (2018b) Porosity and wave velocity evolution of granite after high-temperature treatment: a review. Environ Earth Sci 77(9):350
Zhang W, Sun Q, Zhu Y, Guo W (2019) Experimental study on response characteristics of micro–macroscopic performance of red sandstone after high-temperature treatment. J Therm Anal Calorim 136(5):1935–1945
Zhao Z, Jing H, Shi X, Gao Y (2020) Experimental and numerical research on fracture behaviors of sandstone under different loading rates. Geomech Geophys Geo Energy Geo Resour 6(4):1–17
Zheng L, Rutqvist J, Steefel C, Kim K, Chen F, Vilarrasa V, Nakagawa S, Houseworth J, Birkholzer J (2014) Investigation of Coupled processes and impact of high temperature limits in argillite rock. US Department of Energy, Lawrence Berkeley National Laboratory, Berkeley
Zhu T, Jing H, Su H, Yin Q, Du M, Han G (2016) Physical and mechanical properties of sandstone containing a single fissure after exposure to high temperatures. Int J Min Sci Technol 26(2):319–325
Zhu Z, Tian H, Jiang G, Cheng W (2018) Effects of high temperature on the mechanical properties of Chinese marble. Rock Mech Rock Eng 51(6):1937–1942
Acknowledgements
The authors would like to acknowledge Miss Yujie Liu for her help with laboratory testing.
Author information
Authors and Affiliations
Contributions
SVP: Conceptualization, Methodology, Software, Validation, Formal analysis, Investigation, Resources, Writing- Original Draft, Visualization, IG: Conceptualization, Methodology, Validation, Resources, Writing- Review & Editing, Supervision, Project administration, RK: Software, Formal analysis.
Corresponding author
Ethics declarations
Conflict of interest
The authors declare that they have no conflict of interest.
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
About this article
Cite this article
Vidana Pathiranagei, S., Gratchev, I. & Kong, R. Engineering properties of four different rocks after heat treatment. Geomech. Geophys. Geo-energ. Geo-resour. 7, 16 (2021). https://doi.org/10.1007/s40948-020-00211-8
Received:
Accepted:
Published:
DOI: https://doi.org/10.1007/s40948-020-00211-8