Abstract
The quantification microstructural parameters has gained significant attention to estimate the strength of rock materials. Some researchers have qualitatively explained the influence of microstructural parameters on rock mechanical properties and many developed empirical relations between various microstructural indices and engineering properties of different rock types. A comprehensive review on the relation between microstructure and strength of rock materials has been carried out in this study based on the available literature and the tests performed on granite and sandstone from Malanjkhand and Kothagudem respectively. It has been observed that the correlation of rock strength with mineral content, textural parameters and micro-crack patterns does not signifies any perceptible correlation or any definite trend. This is attributed to the fact that rock strength is a manifestation of cumulative responses of a number of microstructural parameters and thus, correlating rock strength with any single parameter would overlook the impact of others. The study also discusses the challenges and potential benefits of both quantitative and qualitative analysis of microstructure in rock mechanics, providing a way forward for future research in the field. It is ascertained that microstructural studies are time consuming approach and involve significant limitations when quantifying the parameters from the microscopical images and relating them individually with strength of the rocks. However, they might be an important aspect in comprehending the variation in strength and deformation of rock materials and in this respect the implication of modern technological setups would be efficient over the conventional methods.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Data Availability
Data will be made available if asked and required.
References
Akesson U, Stingh J, Lindqvist JE, Goransson M (2001) Relationship between texture and mechanical properties of granites, Central Sweden, by use of image analyzing techniques. Bull Eng Geol Environ 60:277–284
Akesson U, Stigh J, Lindqvist JE, Gorransson M (2003) The influence of foliation on the fragility of granitic rocks, image analysis and quantitative microscopy. Eng Geol 68:275–288
Akesson U, Hansson J, Stigh J (2004) Characterization of microcracks in the Bohus granite, western Sweden, caused by uniaxial cyclic loading. Eng Geol 72:131–142
Alber M, Kahraman S (2009) Predicting the uniaxial compressive strength and elastic modulus of a fault breccia from texture coefficient. Rock Mech Rock Eng 42:117–125
Askaripour M, Saeidi A, Mercier-Langevin P, Rouleau A (2022) A review of relationship between texture characteristic and mechanical properties of rock. Geotech 2:262–296
Azzoni A, Bilo F, Rondena E, Zaninetti A (1996) Assessment of texture coefficient for different rock types and correlation with uniaxial compressive strength and rock weathering. Rock Mech Rock Eng 29:36–46
Basu A, Celestino TB, Bortolucci AA (2009) Evaluation of rock mechanical behaviours under uniaxial compression for different weathering grades. Rock Mech Rock Eng 42:73–93
Basu A, Mishra DA, Roychowdhury K (2013) Rock failure modes under uniaxial compression, Brazilian, and point load tests. Bull Eng Geol Environ 72:457–475
Basu A (2006) Mechanical characterization of granitic rocks of Hong Kong by improved index testing procedures with reference to weathering induced microstructural changes. PhD thesis, The University of Hong Kong
Bell FG (1978) The physical and mechanical properties of the fell sandstone, Nothumberland, England. Eng Geol 12:1–29
Bell FG (2013) Engineering properties of soils and rocks Elsevier
Brattli B (1992) The influence of geological factors on the mechanical properties of basic igneous rocks used as road surface aggregates. Eng Geol 33:31–44
Cantisani E, Garzonio CA, Ricci M, Vettori S (2013) Relationships between the petrographical, physical and mechanical properties of some Italian sandstones. Int J Rock Mech Min Sc 60:321–332
Comakli R, Cayirli S (2019) A correlative study on textural properties and crushability of rocks. Bull Eng Geol Environ 78:3541–3557
Diamantis K, Fereidooni D, Khajevand R, Migiros G (2021) Effect of textural characteristics on engineering properties of some sedimentary rocks. J Cent South Univ 28:926–938
Dobereiner L, Freitas MD (1986) Geotechnical properties of weak sandstones. Geotechnique 36:79–94
Dreyer W (1973) The science of rock mechanics, part 1: the strength properties of rocks. Trance Tech Publications, Cleveland, p 501
Eberhardt E, Stead D, Stimpson B, Read RS (1998) Identifying crack initiation and propagation thresholds in brittle rock. Can Geotech J 35:222–233
Ekran Y (1971) Influence of some structural parameters on the compressive strength of granite. Rock Mech Rock Eng 3:113–120
Ersoy A, Waller MD (1995) Textural characterisation of rocks. Eng Geol 39:123–136
Fahy MP, Guccione MJ (1979) Estimating strength of sandstone using petrographic thin-section data. Bul Assoc Eng Geol 16(4):467–485
Fereidooni D (2022) Importance of the mineralogical and textural characteristics in the mechanical properties of rocks. Arab J Geo Sc 15:637
Gunsallus KL, Kulhawy FH (1984) A comparative evaluation of rock strength measures. Int J Rock Mech Min Sc Geomech 21:233–248
Hamdi P, Stead D, Elmo D (2015) Characterizing the influence of stress-induced microcracks on the laboratory strength and fracture development in brittle rocks using a finite-discrete element method-micro discrete fracture network FDEM-μDFN approach. J Rock Mech Geotech Eng 7:609–625
Hatzor YH, Plachik V (1997) The influence of grain size and porosity on crack initiation stress and critical flaw length in dolomites. Int J Rock Mech Min Sc 34:805–816
Hatzor YH, Plachik V (1998) A microstructure-based failure criterion for Aminadav dolomites. Int J Rock Mech Min Sc 35:797–805
Hemmati A, Ghafoori M, Moomivand H, Lashkaripour GR (2020) The effect of mineralogy and textural characteristics on the strength of crystalline igneous rocks using image-based textural quantification. Eng Geol 266:105467
Hencher SR, Martin RP (1982) The description and classification of weathered rocks in Hong Kong for engineering purposes. In: Proceedings of 7th Southeast Asian Geotech. Conf. Hong Kong. pp 125–142
Hoagland RG, Hahn GT, Rosenfield AR (1973) Influence of microstructure on fracture propagation of rock. Rock Mech Rock Eng 5:77–106
Howarth DF (1988) Experimental study on the relationship between rock texture and mechanical performance. Trans Inst Min Metall 95:41–50
Howarth DF, Rowlands JC (1986) Development of an index to quantify rock texture for qualitative assessment of intact rock properties. Geotech Test J 9:169–179
Howarth DF, Rowlands JC (1987) Quantitative assessment of rock texture and correlation with drillability and strength properties. Rock Mech Rock Eng 20:57–85
Kahn JS (1956) The analysis and distribution of the properties of packing in sand-size sediments: 1. On the measurement of packing in sandstones. J Geol 64:385–395
Kamani M, Ajalloeian R (2019) Evaluation of engineering properties of some carbonate rocks trough corrected texture coefficient. Geotech Geol Eng 37:599–614
Khanlari GR, Heidari M, Sepahigero AA, Fereidooni D (2014) Quantification of strength anisotropy of metamorphic rocks of the Hamedan province, Iran, as determined from cylindrical punch, point load and Brazilian tests. Eng Geol 169:80–90
Krumbein WC (1941) Measurement and geological significance of shape and roundness of sedimentary particles. J Sediment Res 11:64–72
Lajtai EZ (1998) Microscopic fracture processes in a granite. Rock Mech Rock Eng 31:237–250
Li L, Lee PKK, Tsui Y, Tham LG, Tang CA (2003) Failure process of granite. Int J Geomech 3:84–98
Li S, Ren J, Kasyap SS, Senetakis K (2022) Mechanical, micro-structure and contour mapping analyses of highly-porous intermediate-texture analog rock from instrumented micro-indentation in conjunction with statistical/machine learning tools. Geomech Geophy Geo-Energy Geo-Resour 8:99
Li L (2001) Microscopic study and numerical simulation of the failure process of granite. PhD Thesis, The University of Hong Kong
Lindqvist JE, Akesso U, Malaga K (2007) Microstructure and functional properties of rock materials. Mate Charact 58:1183–1188
Lindqvist S, Goransson MJ (2001) Evaluation and interpretation of microscopic parameters versus mechanical properties of Precambrian rocks from the Stockholm region, Sweden. In: Proceedings of the eighth Euro seminar on microscopy applied to building materials, Athens Department de Geologie Athens, pp 13–20
Lois-Morales P, Evans C, Weatherley D (2023) Quantifying the relationship between particles’ strength and their mineralogical and textural characteristics. Min Eng 199:108113
Lounsbery RW, West TR (1965) Petrography of some Indiana aggregates in relation to their engineering properties. Uni Kentucky Eng Exp Station Bul Series 20:24–41
Nasseri MHB, Mohanty B, Robin F (2005) Characterization of microstructures and fracture toughness in five granitic rocks. Int J Rock Mech Min Sc 42:450–460
Nishiyama T, Kusuda H (1996) Application of a fluorescent technique to study of the weathering process. Eng Geol 43:247–253
Norrish K, Taylor R (1962) Quantitative analysis by X-ray diffraction. Clay Min Bull 5:98–109
Onodera TF, Asoka Kumara HM (1980) Relation between texture and mechanical properties of crystalline rocks. Bull Int Assoc Eng Geol 22:173–177
Ozturk CA, Nasuf E (2013) Strength classification of rock material based on textural properties. Tun Undergr Space Tech 37:45–54
Peng J, Wong LNY, Teh CI (2017) Influence of grain size heterogeneity on strength and microcracking behavior of crystalline rocks. J Geophy Res Solid Earth 122:1054–1073
Petruk W (1986) Image analysis: an overview of developments CAMNET Report 86–4E, pp 5
Phillipson SE (2008) Texture, mineralogy, and rock strength in horizontal stress-related coal mine roof falls. Int J Coal Geol 75(3):175–184 https://doi.org/10.1016/j.coal.2008.05.018
Prikryl R (2001) Some microstructural aspects of strength variation in rocks. Int J Rock Mech Min Sc 38:671–682
Prikryl R (2006) Assessment of rock geomechanical quality by quantitative rock fabric coefficients: limitations and possible source of misinterpretations. Eng Geol 87:149–162
Rahimi MR, Mohammadi SD, Beydokhti AT (2020) Effects of mineral composition and texture on durability of sulfate rocks in Gachsaran formation. Iran Geotech Geol Eng 38:2619–2637
Ram BK, Gupta V (2024) Physico-mechanical characterization of Higher Himalayan granite under the thermal treatments of different heating–cooling conditions. Acta Geoteh. https://doi.org/10.1007/s11440-023-02224-5
Roshan H, Masoumi H, Zhang Y, Al-Yaseri AZ, Iglauer S, Lebedev M, Sarmadivaleh M (2018) Microstructural effects on mechanical properties of shaly sandstone. J Geotech Geoenviron Eng 144:06017019
Shakoor A, Bonelli RE (1991) Relationship between petrographic characteristics, engineering index properties and mechanical properties of selected sandstone. Bull Assoc Eng Geol 28(1):55–71
Shuai W, Ying X, Yanbo Z, Xulong Y, Peng L, Xiangxin L (2023) Effects of sandstone mineral composition heterogeneity on crack initiation and propagation through a microscopic analysis technique. Int J Rock Mech Min Sc 162:105307
Sousa LM (2013) The influence of the characteristics of quartz and mineral deterioration on the strength of granitic dimensional stones. Environ Earth Sci 69:1333–1346
Sousa LMO, Suarez del Rio LM, Calleja L, Ruiz de Argandona VG, Rey AR (2005) Infuence of microfractures and porosity on the physico-mechanical properties and weathering of ornamental granites. Eng Geol 77:153–168
Sun W, Wang L, Wang Y (2017) Mechanical properties of rock materials with related to mineralogical characteristics and grain size through experimental investigation: a comprehensive review. Front Struct Civ Eng 11:322–332
Taheri-Garavand A, Abdi Y, Momeni E (2024) Smart estimation of sandstones mechanical properties based on thin section image processing techniques. J Nondest Eval 43:42
Tandon RS, Gupta V (2013) The control of mineral constituents and textural characteristics on the petrophysical & mechanical (PM) properties of different rocks of the Himalaya. Eng Geol 153:125–143
Taylor JM (1950) Pore-space reduction in sandstones. AAPG Bull 34:701–716
Tsidzi KEN (1986) A quantitative petrofabric characterization of metamorphic rocks. Bull Int Assoc Eng Geol 33:3–12
Tsidzi KEN (1990) The influence of foliation on point load strength anisotropy of foliated rocks. Eng Geol 29:49–58
Tugrul A, Zarif IH (1999) Correlation of mineralogical and textural characteristics with selected granitic rocks from Turkey. Eng Geol 51:303–317
Ulusay R, Tureli K, Ider MH (1994) Prediction of engineering properties of a selected litharenite sandstone from its petrographic characteristics using correlation and multivariate statistical techniques. Eng Geol 38:135–157
Ündül Ö (2016) Assessment of mineralogical and petrographic factors affecting petro-physical properties, strength and cracking processes of volcanic rocks. Eng Geol 210:10–12
Vutukuri VS, Lama RD, Saluja SS (1974) Handbook on mechanical properties of rocks. Tech Publication, Clausthal, p 280
Wadell H (1932) Volume, shape, and roundness of rock particles. J Geol 40:443–451
Willard RJ, McWilliams JR (1969) Microstructural techniques in the study of physical properties of rocks. Int J Rock Mech Min Sc 6:1–12
Yesiloglu-Gultekin N, Sezer EA, Gokceoglu C, Bayhan H (2013) An application of adaptive neuro fuzzy inference system for estimating the uniaxial compressive strength of certain granitic rocks from their mineral contents. Exp Sys App 40:921–928
Yilmaz NG, Goktan RM, Kibici Y (2011) Relation between some quantitative petrographic characteristics and mechanical strength properties of granitic building stones. Int J Rock Mech Min Sc 48:506–513
Yusof NQAM, Zabidi H (2016) Correlation of mineralogical and textural characteristics with engineering properties of granitic rock from Hulu Langat, Selangor. Proc Chem 19:975–980
Zorlu K, Ulusay R, Ocakoglu F, Gokceoglu C, Sonmez H (2004) Predicting intact rock properties of selected sandstones using petrographic thin-section data. Int J Rock Mech Min Sc 41:93–98
Zorlu K, Gokceoglu C, Ocakoglu F, Nefeslioglu HA, Acikalin S (2008) Prediction of uniaxial compressive strength of sandstone using petrography-based models. Eng Geol 96:141–158
Acknowledgements
The authors are thankful to the Editor in Chief and both the anonymous reviewers for a constructive review that helped enhance the quality of the manuscript. Prof. Arindam Basu is gratefully acknowledged for his support and suggestion for carrying out this research. The authors are also thankful to Malanjkhand Copper Project and Singareni Colliery Company Limited for providing granite and sand-stone cores, respectively. The second author gratefully acknowledges the SERB India for the NPDF fellowship (File no: PDF/2022/02111) at Indian Institute of Petroleum and Energy (IIPE).
Funding
No funding was received for conducting this study.
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Conflict of interest
No potential conflict of interest was reported by the author.
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Springer Nature or its licensor (e.g. a society or other partner) holds exclusive rights to this article under a publishing agreement with the author(s) or other rightsholder(s); author self-archiving of the accepted manuscript version of this article is solely governed by the terms of such publishing agreement and applicable law.
About this article
Cite this article
Mishra, D.A., Ram, B.K. A Review on Evaluation of Microstructural Parameters to Estimate the Strength of Virtually Isotropic Rock Materials. Geotech Geol Eng (2024). https://doi.org/10.1007/s10706-024-02802-8
Received:
Accepted:
Published:
DOI: https://doi.org/10.1007/s10706-024-02802-8