研究成果在International Journal of Rock Mechanics and Mining Sciences、Rock Mechanics and Rock Engineering、Computers and Geotechnics、岩石力学与工程学报等岩石力学顶级期刊发表学术论文60余篇，部分成果如下：

[1]    Zhou, C., Qiu, J., Karakus, M., Wang, C., Feng, F., Wang, F., Zhou, T. (2026). Unraveling rate-strengthening and fracture-weakening effects in fractured rock masses: A hybrid bonded particle model-discrete fracture network and physics-inspired machine learning framework. Journal of Rock Mechanics and Geotechnical Engineering.

[2]    Zhou, C., Lyu, B., Wang, Y. (2025). Physics-Informed Sparse Dictionary Learning (PISDL) for Accurate Rock Strength Prediction and Extrapolation from Sparse Measurements. Rock Mechanics and Rock Engineering, 1-20.

[3]    Zhou, C., Rui, Y., Qiu, J., Wang, Z., Zhou, T., Long, X., Shan, K. (2025). The role of fracture in dynamic tensile responses of fractured rock mass: Insight from a particle-based model. International Journal of Coal Science & Technology, 12(1), 39.

[4]    Zhou, C., Lyu, B., Wang, Y. (2025). FracGen: natural fracture networks reconstruction and upscaling using generative adversarial networks. International Journal of Rock Mechanics and Mining Sciences, 191, 106116.

[5]    Zhou, C., Xie, H., Zhu, J. (2024). Revealing size effect and associated variability of rocks based on BPM–μ DFN modelling: significance of internal microstructure and strain rate. Rock Mechanics and Rock Engineering, 57(4), 2983-2996.

[6]    Zhou, C., Xie, H., Wang, Z., Zhou, T., Zhu, J. (2023). A novel fractal-statistical scaling model of rocks considering strain rate. Journal of Rock Mechanics and Geotechnical Engineering, 15(11), 2831-2841.

[7]    Zhou, C., Xie, H., Zhu, J., Wang, Z., Li, C., Wang, F. (2022). Mechanical and fracture behaviors of brittle material with a circular inclusion: insight from infilling composition. Rock Mechanics and Rock Engineering, 55(6), 3331-3352.

[8]    Zhou, C., Xie, H., Zhu, J., Zhou, T. (2022). Failure criterion considering high temperature treatment for rocks from a micromechanical perspective. Theoretical and Applied Fracture Mechanics, 118, 103226.

[9]    Zhou, C., Xu, C., Karakus, M., Shen, J. (2019). A particle mechanics approach for the dynamic strength model of the jointed rock mass considering the joint orientation. International Journal for Numerical and Analytical Methods in Geomechanics, 43(18), 2797-2815.

[10] Zhou, T., Chen, J., Wang, F., Zhou, C.* (2024). Uncovering Failure and Cracking Behaviors of Double-Flawed Sandstone Under Compressive-Shear Loading Using Digital Image Correlation (DIC) Technique. Rock Mechanics and Rock Engineering, 57(8), 6183-6209.

[11] Qiu, J., Zhou, C.*, Wang, Z., Feng, F. (2023). Dynamic responses and failure behavior of jointed rock masses considering pre-existing joints using a hybrid BPM-DFN approach. Computers and Geotechnics, 155, 105237.

[12] Zhou, T., Chen, J., Xie, H., Zhou, C.*, Wang, F., Zhu, J. (2022). Failure and mechanical behaviors of sandstone containing a pre-existing flaw under compressive–shear loads: insight from a digital image correlation (DIC) analysis. Rock Mechanics and Rock Engineering, 55(7), 4237-4256.

[13] Yin, X., Zhou, T., Zhou, C.*, Xie, H., Zhu, J. (2023). Rate-and normal stress-dependent mechanical behavior of rock under direct shear loading based on a bonded-particle model (BPM). Rock Mechanics and Rock Engineering, 56(11), 7959-7979.

[14] Wang, Z., Zhou, C.*, Wang, F., Li, C., Xie, H. (2021). Channeling flow and anomalous transport due to the complex void structure of rock fractures. Journal of Hydrology, 601, 126624.

[15]周昌台, 谢和平, 朱建波. (2023). 基于能量理论的岩石动态破坏准则. 岩石力学与工程学报, 42(8), 1890-1898.