Abstract
In this research, a series of triaxial compression experiments and X-ray observations were conducted to explore the strength, deformability and internal damage mechanism of deeply buried marble. The results show that an increase in confining pressure results in obvious brittle–ductile transition characteristics of deeply buried marble. The Young’s modulus of the marble increased nonlinearly with increasing confining pressure. The peak and residual strength of the marble exhibit a clear linear relationship with the confining pressure, which can be described by the linear Mohr–Coulomb criterion. The sensitivity of the residual strength on the confining pressure was clearly higher than that of the peak strength. After uniaxial and triaxial compression failure, marble specimens were analyzed using a three-dimensional X-ray micro-CT scanning system. Based on horizontal and vertical cross-sections, the marble specimen is mainly dominated by axial splitting tensile cracks under uniaxial compression, but under confining pressure, the marble specimen is mainly dominated by a single shear crack. To quantitatively evaluate the internal damage of the marble material, the crack area and aperture extent for each horizontal cross-section were calculated by analyzing the binarized pictures. The system of crack planes under uniaxial compression is more complicated than that under triaxial compression, which is also supported by the evolution of the crack area and aperture extent. Finally, the brittle–ductile transition mechanism of the marble is discussed and interpreted according to the proposed conceptual models.
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References
Akbardoost J, Ayatollahi MR (2014) Experimental analysis of mixed mode crack propagation in brittle rocks: the effect of non-singular terms. Eng Fract Mech 129:77–89
Aliha MRM (2014) Indirect tensile test assessments for rock materials using 3-D disc-type specimens. Arab J Geosci 7(11):4757–4766
Aliha MRM, Ayatollahi MR, Akbardoost J (2012) Typical upper bound–lower bound mixed mode fracture resistance envelopes for rock material. Rock Mech Rock Eng 45(1):65–74
Aliha MRM, Hosseinpour GR, Ayatollahi MR (2013) Application of cracked triangular specimen subjected to three-point bending for investigating fracture behavior of rock materials. Rock Mech Rock Eng 46(5):1023–1034
Ayatollahi MR, Aliha MRM (2007) Fracture toughness study for a brittle rock subjected to mixed mode I/II loading. Int J Rock Mech Min Sci 44:617–624
Chang SH, Lee CI, Jeon S (2002) Measurement of rock fracture toughness under modes I and II and mixed-mode conditions by using disc-type specimens. Eng Geol 66:79–97
Fairhurst CE, Hudson JA (1999) Draft ISRM suggested method for the complete stress–strain curve for the intact rock in uniaxial compression. Int J Rock Mech Min Sci 36(3):279–289
Feng XT, Chen SL, Zhou H (2004) Real-time computerized tomography (CT) experiments on sandstone damage evolution during triaxial compression with chemical corrosion. Int J Rock Mech Min Sci 41(2):181–192
Feng GL, Feng XT, Chen BR, Xiao YX (2015) Microseismic sequences associated with rockbursts in the tunnels of the Jinping II hydropower station. Int J Rock Mech Min Sci 80:89–100
Funatsu T, Kuruppu M, Matsui K (2014) Effects of temperature and confining pressure on mixed-mode (I–II) and mode II fracture toughness of Kimachi sandstone. Int J Rock Mech Min Sci 67:1–8
Ge XR, Ren JX, Pu YB, Ma W, Zhu YL (2001) Real-in time CT test of the rock meso-damage propagation law. Sci China (Ser E) 44(3):328–336
Gui YL, Zhao GF, Khalili N (2012) Experimental investigation of desiccation of clayey soils. In: 22th Australasian conference on the mechanics of structure and materials (ASMSM22), 11–14 Dec, Sydney, Australia
Hirono T, Takahashi M, Nakashima S (2003) In situ visualization of fluid flow image within deformed rock by X-ray CT. Eng Geol 70:37–46
Hirono T, Sakaguchi M, Otsuki K, Sone H, Fujimoto K, Mishima T, Lin W, Tanikawa W, Tanimizu M, Soh W, Yeh EC, Song SR (2008) Characterization of slip zone associated with the 1999 Taiwan Chi-Chi earthquake: X-ray CT image analyses and microstructural observations of the Taiwan Chelungpu fault. Tectonophysics 449:63–84
Huang D, Li YR (2014) Conversion of strain energy in triaxial unloading tests on marble. Int J Rock Mech Min Sci 66:160–168
Jaeger JC, Cook NGW, Zimmerman RW (2007) Fundamentals of rock mechanics, 4th edn. Blackwell Publishing, Oxford
Jiang Q, Feng XT, Xiang TB, Su GS (2010) Rockburst characteristics and numerical simulation based on a new energy index: a case study of a tunnel at 2500 m depth. Bull Eng Geol Environ 69:381–388
Kawakata H, Cho A, Kiyama T, Yanagidani T, Kusunose K, Shimada M (1999) Three-dimensional observations of faulting process in Westerly granite under uniaxial and triaxial conditions by X-ray CT scan. Tectonophysics 313:293–305
Li SJ, Feng XT, Li ZH (2012a) Evolution of fractures in the excavation damaged zone of a deeply buried tunnel during TBM construction. Int J Rock Mech Min Sci 55(10):125–138
Li SJ, Feng XT, Li ZH, Chen BR, Zhang CQ, Zhou H (2012b) In situ monitoring of rockburst nucleation and evolution in the deeply buried tunnels of Jinping II hydropower station. Eng Geol 137(138):85–96
Li XP, Zhao H, Wang B, Xiao TL (2013) Mechanical properties of deep-buried marble material under loading and unloading tests. J Wuhan Univ Technol Mater 28(3):514–520
Meier T, Rybacki E, Backers T, Dresen G (2014) Influence of bedding angle on borehole stability: a laboratory investigation of transverse isotropic oil shale. Rock Mech Rock Eng. doi:10.1007/s00603-014-0654-1
Qiu SL, Feng XT, Xiao JQ, Zhang CQ (2014) An experimental study on the pre-peak unloading damage evolution of marble. Rock Mech Rock Eng 47:401–409
Sufian A, Russell AR (2013) Microstructural pore changes and energy dissipation in Gosford sandstone during pre-failure loading using X-ray CT. Int J Rock Mech Min Sci 57:119–131
Wu SY, Shen MB, Wang J (2010) Jinping hydropower project: main technical issues on engineering geology and rock mass. Bull Eng Geol Environ 69:325–332
Yang SQ, Jiang YZ, Xu WY, Chen XQ (2008) Experimental investigation on strength and failure behavior of pre-cracked marble under conventional triaxial compression. Int J Solids Struct 45:4796–4819
Yang SQ, Dai YH, Han LJ, Jin ZQ (2009) Experimental study on mechanical behavior of brittle marble samples containing different flaws under uniaxial compression. Eng Fract Mech 76:1833–1845
Yang SQ, Xu P, Ranjith PG, Chen GF, Jing HW (2015a) Evaluation of creep mechanical behavior of deep-buried marble under triaxial cyclic loading. Arab J Geosci 8:6567–6582
Yang SQ, Ranjith PG, Huang YH, Yin PF, Jing HW, Gui YL, Yu QL (2015b) Experimental investigation on mechanical damage characteristics of sandstone under triaxial cyclic loading. Geophys J Int 201:662–682
Zhao GF, Russell AR, Zhao XB, Khalili N (2014) Strain rate dependency of uniaxial tensile strength in Gosford sandstone by the Distinct Lattice Spring Model with X-ray micro CT. Int J Solids Struct 51:1587–1600
Acknowledgments
This research was supported by the Fundamental Research Funds for the Central Universities (2015XKZD05). The authors would like to express their sincere gratitude to the editor, Giovani Barla, and two anonymous reviewers for their valuable comments, which have greatly improved this paper.
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Yang, SQ., Ju, Y., Gao, F. et al. Strength, Deformability and X-ray Micro-CT Observations of Deeply Buried Marble Under Different Confining Pressures. Rock Mech Rock Eng 49, 4227–4244 (2016). https://doi.org/10.1007/s00603-016-1040-y
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DOI: https://doi.org/10.1007/s00603-016-1040-y