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Huang, X., Qi, S., Zheng, B., Guo, S., & Zhan, Z. (2020). Progressive failure characteristics of brittle rock under high-strain-rate compression using the bonded particle model. Materials, 13(18).Search in Google Scholar
Moska, P. M. M. (2018). Rock anisotropy and brittleness from laboratory ultrasonic measurements in the service of hydraulic fracturing. Acta geodynamica et geomaterialia, 15(1).Search in Google Scholar
Peng, J., Xu, C., Dai, B., Sun, L., Feng, J., & Huang, Q. (2022). Numerical investigation of brittleness effect on strength and microcracking behavior of crystalline rock. International journal of geomechanics.Search in Google Scholar
Zhenghu, Z., Zhengzhao, L., Chun’An, T., & Kiyoshi, K. (2023). A comparative study of current methods for determining stress thresholds of rock subjected to compression. Rock Mechanics and Rock Engineering(11), 56.Search in Google Scholar
Liu, H. D., Liu, J. J., Zhang, S. Y., Feng, L. Y., & Qiu, L. (2022). Stress-strain and acoustic emission characteristics of cement-based materials used to simulate soft rock with fractures. Scientific reports, 12(1), 7903.Search in Google Scholar
Hashiba, K., Fukui, K., & Kataoka, M. (2018). Modeling of complete stress-strain curves and time-dependent behaviors of rocks under uniaxial tension. MATERIALS TRANSACTIONS, 59(5).Search in Google Scholar
A, G. R. L., A, A. R., & A, M. G. (2018). Assessment of brittleness and empirical correlations between physical and mechanical parameters of the asmari limestone in khersan 2dam site, in southwest of iran. Journal of African Earth Sciences, 138, 124-132.Search in Google Scholar
Chen, G., He, M., & Fan, F. (2018). Rock burst analysis using dda numerical simulation. International Journal of Geomechanics, 18(3), 04018001.1-04018001.12.Search in Google Scholar
Manoj Khandelwal, Roohollah Shirani, Faradonbeh, Masoud Monjezi, Danial Jahed Armaghani, & Muhd Zaimi Bin Abd Majid. (2017). Function development for appraising brittleness of intact rocks using genetic programming and nonlinear multiple regression models. Engineering with Computers.Search in Google Scholar
Machniak, U., & Kozio, W. (2017). Method of assessment of hard rock workability using bucket wheel excavators. Archives of Mining Sciences.Search in Google Scholar
Zuo, J., & Man, S. (2020). Tension and shear cracks growth-based evolution model for creep characteristics of brittle rocks. International Journal of Geomechanics, 20(10), 04020164.Search in Google Scholar
Cielik, J. (2018). Dilatancy as a measure of fracturing development in the process of rock damage. Open Geosciences, 10(1), 484-490.Search in Google Scholar
Seredin, V. V., Khrulev, A. S., & Pushkareva, M. V. (2017). Estimation of stress state in rocks and geomaterials. Journal of Mining Science, 53(1), 49-52.Search in Google Scholar
Wang, L., Yang, H., Guo, Y., Bi, Z., Guo, W., & Yang, C. (2021). Comparative study of marine and lacustrine shale reservoirs from the viewpoint of rock mechanics. Energy & Fuels(23), 35.Search in Google Scholar
Wang, C., Zhan, S. F., Xie, M. Z., Wang, C., & Xiong, Z. Q. (2020). Damage characteristics and constitutive model of deep rock under frequent impact disturbances in the process of unloading high static stress. Complexity, 2020, 1-15.Search in Google Scholar
Cao, A., Jing, G., Ding, Y. L., & Liu, S. (2019). Mining-induced static and dynamic loading rate effect on rock damage and acoustic emission characteristic under uniaxial compression. Safety Science, 116, 86-96.Search in Google Scholar
Samuel, Chapman, Beatriz, & Quintal. (2018). Numerical analysis of local strain measurements in fluid-saturated rock samples submitted to forced oscillationsanalysis of local strain measurements. Geophysics.Search in Google Scholar
Li, J., Zhang, G., Liu, M., Hu, S., & Zhou, X. (2020). Dynamic triaxial constitutive model for rock subjected to initial stress. Open Physics, 18(1), 149-163.Search in Google Scholar
