Abstract
Natural stones are exposed to sudden and slow-developing thermal cycles, affecting their physico-mechanical and surface properties. In this study, changes in the physico-mechanical properties of natural stones in response to sudden (thermal shock) and slow-developing (thermal aging) thermal cycles were investigated on natural stone samples with various compositions (magmatic, sedimentary, metamorphic). Both the thermal shock and thermal aging cycles were simulated by first heating the specimens to 105 °C for 18 h. In case of the thermal shock cycles, the heating phase was followed by placing the samples in purred water for 6 h. To simulate the thermal aging cycles, specimens were allowed to cool at room temperature (23 °C) for 6 h. At the end of the cycles, a selection of physico-mechanical properties was evaluated and compared with the initial values. Results indicate that thermal treatments have a significant negative effect on the strength of the natural stone samples. Regression models were developed to estimate uniaxial compressive strength, point load strength, Brazilian tensile strength from non-destructive test parameters (Schmidt hardness, P wave velocity, porosity) of natural and treated samples. Results show that there are strong correlations between mechanical properties and non-destructive test parameters (R2 > 0.96, MAPE values between 2 and 5%).
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References
Angeli M, Bigas JP, Benavente D, Menendez B, Hebert R, David C (2007) Salt crystallization in pores: quantification and estimation of damage. Eng Geol 52:187–195
Angeli M, Benavente D, Bigas JP, Menendez B, Hebert R, David C (2008) Modification of the porous network by salt crystallization in experimentally weathered sedimentary stones. Mater Struct 41:1091–1108
Beck K, Al-Mukhtar M (2010) Evaluation of the compatibility of building limestones from salt crystallization experiments. Geol Soc Lond Spec Publ 333:111–118
Bonazza A, Messina P, Sabbioni C, Carlota MG, Brimblecombe P (2009) Mapping the impact of climate change on surface recession of carbonate buildings in Europe. Sci Total Environ 407(6):2039–2050
Çelik MY, Aygün A (2018) The effect of salt crystallization on degradation of volcanic building stones by sodium sulfates and sodium chlorides. Bull Eng Geol Environ 78(5):3509–3529
Çelik MY, Sert M (2020) Accelerated aging laboratory tests for the evaluation of the durability of hydrophobic treated and untreated andesite with respect to salt crystallization, freezing–thawing, and thermal shock. Bull Eng Geol Environ 79:3751–3770
Çobanoğlu I, Çelik SB, Dinçer I, Alkaya D (2009) Core size and time effects on water absorption values of rock and cement mortar samples. Bull Eng Geol Environ 68:483–489
Demirdag S (2013) Effects of freezing–thawing and thermal shock cycles on physical and mechanical properties of filled and unfilled travertines. Constr Build Mater 47:1395–1401
Derluyn H, Moonen P, Carmeliet J, Carmeliet J (2014) Deformation and damage due to drying-induced salt crystallization in porous limestone. J Mech Phys Solids 63(1):242–255
Fener M, Ince I (2015) Effects of the freeze–thaw (F–T) cycle on the andesitic rocks (Sille-Konya/Turkey) used in construction building. J African Earth Sci 109:96–106
Feng Y, Su H, Nie Y, Zhao H (2022) Role of cyclic thermal shocks on the physical and mechanical responses of white marble. Machines 20:58. https://doi.org/10.3390/machines10010058
Freire-Lista DM, Fort R, Varas-Muriel MJ (2015) Freeze-thaw fracturing in building granites. Cold Reg Sci Technol 113:40–51
Ghobadi MH, Babazadeh R (2015) Experimental studies on the effects of cyclic freezing-thawing, salt crystallization, and thermal shock on the physical and mechanical characteristics of selected sandstones. Rock Mech Rock Eng 48:1001–1016
Huhta A, Kärki A, Hanski E (2016) A new method for testing thermal shock resistance properties of soapstone – effects of microstructures and mineralogical variables. Bull Geol Soc Finl 88(1):21–46
ISRM (1978a) Suggested method for determining he uniaxial compressive strength and deformability of rock materials. Int J Rock Mech Min Sci Geomech Abstr. https://doi.org/10.1016/0148-9062
ISRM (1978b) Suggested methods for determining sound velocity. Int J Rock Mech Min Sci Geomech Abstr 15:53–58
ISRM (1981) Suggested methods for determining hardness and abrasiveness of rocks. Part 3. commission on standardization of laboratory and field tests. Int J Rock Mech Min Sci Geomech Abstr 15(3):89–97
ISRM (1985) Suggested method for determining point load strength. Int J Rock Mech Min Sci Geomech Abstr 22(2):51–60
ISRM (2007) Suggested methods for determining tensile strength of rock materials. Int J Rock Mech Min Sci 15:99–103
Karaca Z (2010) Water absorption and dehydration of natural stones versus time. Constr Build Mater 24:786–790
Kılıç İ (2017) Physical and mechanical properties of yenimuhacir sandstone as construction material. Gaziosmanpasa J Sci Res 6(3):01–11
Lam dos Santos JP, Rosa LG, Amaral PM (2011) Temperature effects on mechanical behavior of engineered Stones. Constr Build Mater 25:171–174
Liu S, Xu J (2015) An experimental study on the physico-mechanical properties of two post-high-temperature rocks. Eng Geol 185:63–70
Ma Q, Ma D, Yao Z (2018) Influence of freeze-thaw cycles on dynamic compressive strength and energy distribution of soft rock specimen. Cold Reg Sci Technol 153:10–17
Müller U (2008) The mineralogical composition of sandstone and its effect on sulphur dioxide deposition. Mater Constr 58:81–95
Murru A, Freire-Lista DM, Fort R, Varas-Muriel MJ, Meloni P (2018) Evaluation of post-thermal shock effects in Carrara marble and Santa Caterina di Pittinuri limestone. Constr Build Mater 186:1200–1211
Ozcelik Y, Ozguven A (2014) Water absorption and drying features of different natural building stones. Constr Build Mater 63:257–270
Ozcelik Y, Careddu N, Yilmazkaya E (2012) The effects of freeze-thaw cycles on the gloss values of polished stone surfaces. Cold Reg Sci Technol 82:49–55
Ozdemir E, Sarici DE (2018) Combined effect of loading rate and water content on mechanical behavior of natural stones. J Min Sci 54(6):931–937
Ozdemir E, Kantarcı F, Sarıcı DE (2022) Effects of acid–base solutions on some Turkish natural building stones: physico-mechanical and color changes. Innov Infrastruct Solut 7:103
Ozgüven A, Özcelik Y (2014) Effects of high temperature on physico-mechanical properties of Turkish natural building stones. Eng Geol 183:127–136
Sarici DE (2016) Thermal deterioration of marbles: gloss, color changes. Constr Build Mater 102:416–421
Sarici DE, Ozdemir E (2018) Determining point load strength loss from porosity, Schmidt hardness, and weight of some sedimentary rocks under freeze–thaw conditions. Environ Earth Sci 77:62
Sarıcı DE, Kızılkaya N, Özdemir E, Polat F (2018) Evalution of salt crystallisation effects on artificial marble. J Phys Chem Funct Mater 1(2):20–24
Sharma PK, Khandelwal M, Singh TN (2007) Variation on physico-mechanical properties of Kota stone under different watery environments. Build Environ 42:4117–4123
Su H, Jing H, Yin Q, Yu L, Wang Y, Wu X (2017) Strength and deformation behaviors of veined marble specimens after vacuum heat treatment under conventional triaxial compression. Acta Mech Sin 33:886–898
Tan X, Chen W, Yang J, Cao J (2011) Laboratory investigations on the mechanical properties degradation of granite under freeze-thaw cycles. Cold Reg Sci Technol 68:130–138
TS EN 14066 (2004) Doğal Taşlar-Deney Metodları-Termal Şok Etkisiyle Yıpranmaya Direncin Tayini, TSE, Ankara (in Turkish)
TS EN 1925 (2000) Natural stone test methods: determination of water absorption coefficient by capillarity, TSE, Ankara (in Turkish)
Vásárhelyi B, Ván P (2006) Influence of water content on the strength of rock. Eng Geol 84:70–74
Vazquez P, Carrizo L, Thomachot-Schneider C, Gibeaux S, Alonso FJ (2016) Influence of surface finish and composition on the deterioration of building stones exposed to acid atmospheres. Constr Build Mater 106:392–403
Wang P, Xu J, Liu S, Wang H (2016a) Dynamic mechanical properties and deterioration of red-sandstone subjected to repeated thermal shocks. Eng Geol 212:44–52
Wang P, Xu J, Liu S, Wang H, Liu S (2016b) Static and dynamic mechanical properties of sedimentary rock after freeze-thaw or thermal shock weathering. Eng Geol 210:148–157
Yavuz H (2011) Effect of freeze–thaw and thermal shock weathering on the physical and mechanical properties of an andesite stone. Bull Eng Geol Environ 70:187–192
Yavuz AB, Topal T (2007) Thermal and salt crystallization effects on marble deterioration: examples from Western Anatolia, Turkey. Eng Geol 90:30–40
Yavuz H, Altindag R, Sarac S, Ugur I, Sengun N (2006) Estimating the index properties of deteriorated carbonate rocks due to freeze–thaw and thermal shock weathering. Int J Rock Mech Min Sci 43(5):767–775
Zhang W, Sun Q, Hao S, Geng J, Lv C (2016) Experimental study on the variation of physical and mechanical properties of rock after high temperature treatment. Appl Therm Eng 8:1297–1304
Zhou Z, Cai X, Cao W, Li X, Xiong C (2016) Influence of water content on mechanical properties of rock in both saturation and drying processes. Rock Mech Rock Eng 49:3009–3025
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Authors are grateful for financial support from Inonu University Research Funding. (Inonu University, Project No: FDK-2017-879).
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Özdemir, E., Eren Sarıcı, D. Effects of thermal shock and aging on natural stones: an experimental and statistical study. Acta Geod Geophys 58, 285–304 (2023). https://doi.org/10.1007/s40328-023-00410-1
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DOI: https://doi.org/10.1007/s40328-023-00410-1