This paper investigates the mechanical properties and damage laws of marine shale from the Silurian Longmaxi Formation by conducting uniaxial compression experiments with varying lamination angles with respect to the loading direction. Data are analyzed via computed tomography scanning and fractal theory to reveal a series of mechanical properties, considering stress-strain curve, compressive strength, Young’s modulus, and Poisson’s ratio. The results indicate three damage modes in shale samples: shear, tension shear, and tension. The shales are anisotropic as the mechanical properties vary with the lamination orientation and the loading direction. The compressive strength decreases nonlinearly with increasing lamination angle, whereas the Young’s modulus and Poisson’s ratio correlate almost linearly with the lamination angle. To overcome the defect of visual images when quantitatively evaluating cracks and rock damage to investigate the mechanical properties of shale, we propose block fractal dimension and crack fractal dimensions calculated using post-experimental photographs and computed tomography images. Fractal dimensions are useful tools for identifying variations in uniaxial compressive strength and correlate positively with the sample damage, particularly their damage class. This study highlights the value of applying fractal theory for the quantitative characterization of shale mechanical properties, and reveals that the lamination orientation to the loading direction is a parameter that significantly controls the mechanical properties of shale.

Document Type: Original article

Cited as: Gao, M., Yang, M., Lu, Y., Levin, V. A., He, P., Zhu, H. Mechanical characterization of uniaxial compression associated with lamination angles in shale. Advances in Geo-Energy Research, 2024, 13(1): 56-68. https://doi.org/10.46690/ager.2024.07.07

Alex, V., Ahmad, G. Damage characteristics of three shales under true-triaxial compression. International Journal of Rock Mechanics and Mining Sciences, 2017, 100: 151-159.

Amir, B. Y., Andy, W., Patrick, F. Application of a densityvolume fractal model for rock characterisation of the Kahang porphyry deposit. International Journal of Rock Mechanics and Mining Sciences, 2014, 66: 188-193.

Arora, S., Mishra, B. Investigation of the failure mode of shale rocks in biaxial and triaxial compression tests. International Journal of Rock Mechanics and Mining Sciences, 2015, 79: 109-123.

Bagde, M. N., Raina, A. K., Chakraborty, A, K., et al. Rock mass characterization by fractal dimension. Engineering Geology, 2002, 63(1-2): 141-155.

Boris, G., Anna, G., Evgenij, K., et al. Strength equation of composite materials and fractal dimension of cracks. Energy Reports, 2021, 7(5): 569-578.

Gao, J., Li, X., Cheng, G., et al. Structural evolution and characterization of organic-rich shale from macroscopic to microscopic resolution: The significance of tectonic activity. Advances in Geo-Energy Research, 2023, 10(2): 84-90.

Gholami, R., Rasouli, V. Mechanical and elastic properties of transversely isotropic shale. Rock Mechanics and Rock Engineering, 2014, 47(5): 1763-1773.

González-Tello, P., Camacho, F., Vicaria, J. M., et al. A modified Nukiyama-Tanasawa distribution function and a Rosin-Rammler model for the particle-size-distribution analysis. Powder Technology, 2008, 186(3): 278-281.

He, M., Zhao F., Du S., et al. Experimental analysis of rock burst damage characteristics under different unloading rates. Rock and Soil Mechanics, 2014, 35(10): 2737-2747 + 2793. (in Chinese)

Li, G., Jin, Z., Li, X., et al. Experimental study on mechanical properties and fracture characteristics of shale layered samples with different mineral components under cyclic loading. Marine and Petroleum Geology, 2023, 150: 106114.

Li, M. Research on damage and crack mechanism of coal measure sandstone under high temperature and impact load. Xuzhou, China University of Mining and Technology, 2014. (in Chinese)

Li, Y., Song, L., Tang, Y., et al. Evaluating the mechanical properties of anisotropic shale containing bedding and natural fractures with discrete element modeling. International Journal of Coal Science & Technology, 2022, 9(2): 16.

Liu, B., Wang, S., Ke, X. Mechanical characteristics and factors controlling brittleness of organic-rich continental shales. Journal of Petroleum Science and Engineering, 2020, 194: 107464.

Mandelbrot, B. B. The fractal geometry of nature. American Journal of Physics, 1983, 51(3): 286-286.

Marie, L. T. D., Morteza, N., Daniel, V. On the direct measurement of shear moduli in transversely isotropic rocks using the uniaxial compression test. International Journal of Rock Mechanics and Mining Sciences, 2019, 113: 220-240.

Niloufar, M., Fatemeh, M. Theoretical and experimental in vestigation of a shear failure model for anisotropic rocks using direct shear test. International Journal of Rock Mechanics and Mining Sciences, 2023, 170: 105561.

Peng, R., Yang Y., Ju, Y., et al. Calculation of fractal dimension of rock pores based on gray-scale CT images. Chinese Science Bulletin, 2011, 56(26): 2256-2266. (in Chinese)

Rickman, R., Mullen, M., Petre, E., et al. A practical use of shale petrophysics for stimulation design optimization: All shale plays are not clones of the Barnett Shale. Paper SPE 115258 Presented at the SPE Annual Technical Conference and Exhibition, Denver, Colorado, USA, 21-24 September, 2008.

Rybacki, E., Reinicke, A., Meier T., et al. What controls the mechanical properties of shale rocks?-Part I: Strength and Young’s modulus. Journal of Petroleum Science and Engineering, 2015, 135: 702-722.

Sahimi, M. Flow and Transport in Porous Media and Fractured Rock: From Classical Methods to Modern Approaches. Weinheim, Germany, John Wiley & Sons, 2011.

Sarout, J., Molez, L., Guéguen, Y., et al. Shale dynamic properties and anisotropy under triaxial loading: Experimental and theoretical investigations. Physics and Chemistry of the Earth, 2007, 32(8-14): 896-906.

Sethi, C., Hazra, B., Ostadhassan, M., et al. Depositional environmental controls on mechanical stratigraphy of Barakar Shales in Rajmahal Basin, India. International Journal of Coal Geology, 2024, 285: 104477.

Sui, L., Ju, Y., Yang, Y., et al. A quantification method for shale fracability based on analytic hierarchy process. Energy, 2016, 115: 637-645.

Su, Y., Sun, Q., Wang, W., et al. Spontaneous imbibition characteristics of shale oil reservoir under the infuence of osmosis. International Journal of Coal Science & Technology, 2022, 9(5): 48-58.

Velde, B., Dubois, J., Moore, D., et al. Fractal patterns of fractures in granites. Earth and Planetary Science Letters, 1991, 104(1): 25-35.

Wang, H., Cui, Y., Yuan, G., et al. Fractal characteristics of granite with different weathering degrees based on uniaxial compression test. Rock and Soil Mechanics, 2023, 44(8): 2249-2265. (in Chinese)

Xiao, C., Yang, R., Ma, X. Damage evaluation of rock blasting based on multi-fractal study. International Journal of Impact Engineering, 2024, 188: 104953.

Xu, S., Yang, H., Li, L., et al. Real-time evaluation method of rock mechanical parameters based on rock chip fractaltheory. Science Technology and Engineering, 2023, 23(32): 13803-13810. (in Chinese)

Zhao, L., Mao, W., Liu, Z., et al. Research on the differential tectonic-thermal evolution of Longmaxi shale in the southern Sichuan Basin. Advances in Geo-Energy Research, 2023, 7(3): 152-163.

Zhao, Q., Yang, S., Wang, H., et al. China’s shale gas development and its prospects. Environmental Impact Assessment, 2019, 41(1): 6-10. (in Chinese)

Zhu, H., Huang, C., Ju, Y., et al. Multi-scale multi-dimensional characterization of clay-hosted pore networks of shale using FIBSEM, TEM, and X-ray micro-tomography: Implications for methane storage and migration. Applied Clay Science, 2021, 213: 106239.