Physical Alteration and Color Change of Granite Subjected to High Temperature

Németh, Andor; Antal, Ákos; Török, Ákos

doi:10.3390/app11198792

Cited by 2 publications

(2 citation statements)

References 49 publications

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“…Colour parameters, such as chroma and lightness, change in quartz and feldspar due to microcracking development [14]. Hue change is also noticeable in mica, clays, and iron oxides mainly due to iron thermal oxidation, which causes yellowing and reddening [12,[14][15][16][17][18][19]. Volume increase and roughness changes as a consequence of thermal expansion have been also evaluated [14,20,21].…”

Section: Introductionmentioning

confidence: 99%

“…One of the main objectives of heating tests of rocks is assessing how their cracking dynamics and strength decrease with temperature [22][23][24]. For this purpose, previous research used non-destructive indirect methods such as p-waves velocity, capillary water uptake, and porosity variations [12,13,19,[25][26][27], as well as direct methods such as compression or flexural strength tests [24,28,29]. Most of these tests were carried out after the rock specimens were heated to a certain target temperature and cooled down to room temperature.…”

Section: Introductionmentioning

confidence: 99%

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Mineralogical Transformations in Granitoids during Heating at Fire-Related Temperatures

et al. 2021

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Fire is a major decay agent of rocks and can generate immediate catastrophic effects as well as directional and anisotropic damage that affect long-term weathering processes. Temperature increase is the most relevant factor, among other components in a fire, generating mineral transformations and bulk mechanical damage. Mineralogical changes at high temperatures are key to understanding the overall mechanical behaviour. However, most studies to date were carried out after rock specimens were heated to a target temperature and cooled down to room temperature. Therefore, these studies are missing the observation of the actual mineral processes during heating. This paper aims to compare mineralogical changes in crystalline rocks during heating by means of XPS and different XRD techniques. Samples of four different granitoids were heated to several temperatures up to 1000 °C to evaluate their chemical and structural changes. Results show how standardised thermal expansion coefficients are not a suitable indicator of the bulk effect of high temperatures on rocks. Results also show how thermal expansion estimations from XRD lattice measurements may be an alternative to bulk dilatometric tests, as they can be performed with limited sampling, which may be necessary in some studies. Nevertheless, XRD and XPS results need to be interpreted carefully in relation to the bulk effects of temperature increase in the rocks, as the structural behaviour may seemingly contradict the macroscopic effect.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Mineralogical Transformations in Granitoids during Heating at Fire-Related Temperatures

et al. 2021

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Statistical analysis of heat-induced rock physics and mineralogical alteration processes of monzogranite samples from Bátaapáti, Hungary

Németh,

Török

2023

Int J Geomath

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Heat-induced physical changes of rocks, as would happen in fire accidents, have crucial importance in the long-term stability of underground openings such as tunnels or radioactive waste disposal chambers. The thermal behaviour of monzogranite from the Radioactive waste repository of Bátaapáti (Hungary) was studied in that context. Room temperature (22 °C) and a series of high temperature (250 °C, 375 °C, 500 °C, 625 °C, 750 °C) heat-treated samples were tested. P and S- ultrasound pulse velocity, bulk density, Duroskop rebound, uniaxial compressive strength, and modulus of elasticity were measured and compared, detecting temperature-related changes. Descriptive statistics and non-parametric Kruskal–Wallis and Median tests were carried out to analyze the heat-induced rock mechanical and mineralogical alteration processes. Based on these results using the data set of physical parameters, it is possible to predict the heating temperature of granitic rocks when the firing or heat stress conditions are unknown. Additionally, the data could be utilized for design and monitoring systems in underground repositories or tunnel systems constructed in granitic rock settings globally. The study demonstrated that significant alteration occurs above 500 °C; all studied rock-mechanical parameters decreased rapidly. These changes are linked to the thermal expansion, micro-cracking in micro-fabric, and volumetric increase and fragmentation of quartz inversion. Consequently, the propagation velocities of P- and S-waves also decreased significantly. Bulk density and Duroskop surface strength significantly decreased above 375 °C, while uniaxial compressive strength and modulus of elasticity dropped drastically at 750 °C after a linear decrease.

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Physical Alteration and Color Change of Granite Subjected to High Temperature

Cited by 2 publications

References 49 publications

Mineralogical Transformations in Granitoids during Heating at Fire-Related Temperatures

Mineralogical Transformations in Granitoids during Heating at Fire-Related Temperatures

Statistical analysis of heat-induced rock physics and mineralogical alteration processes of monzogranite samples from Bátaapáti, Hungary

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