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All issues Volume 293 (2021) E3S Web Conf., 293 (2021) 03008 References
Open Access
Issue
E3S Web Conf.
Volume 293, 2021
2021 3rd Global Conference on Ecological Environment and Civil Engineering (GCEECE 2021)
Article Number 03008
Number of page(s) 7
Section Sustainable Resource Development and Green Energy Saving
DOI https://doi.org/10.1051/e3sconf/202129303008
Published online 23 July 2021
  1. Y. Chahra, B. Riad, T. Mustapha. Application of classification systems for the assessment of rock mass stability—case of national road 43, Jijel, Algeria. Arab. J. Geosci. 14, 3. (2021) [Google Scholar]
  2. S. Tao, Y. Baoquan, C. Yuan, et al. Research on the Stability of Dam Foundation of a Sluice Dam Project in the Pearl River. IOP Conference Series: Earth and Environmental Science. 768, 1. (2021) [Google Scholar]
  3. C.H. Scholz Wear and gouge formation in brittle faulting. Geology. 15, 6, 493–495. (1987) [Google Scholar]
  4. W.W. Chen, W.F. Han, X.G. Zhang. Engineering Geology of the Fault Rock. Beijing, China. (2008) (In Chinese) [Google Scholar]
  5. J.T. Engelder. Cataclasis and the Generation of Fault Gouge. GSA. Bulletin. 85, 10, 1515–1522. (1974) [Google Scholar]
  6. R.H. Sibson Fault rocks and fault mechanisms. J. Geol. Soc. 133, 3, 191–213. (1977) [Google Scholar]
  7. E.H. Rutter, R.H. Maddock, S.H. Hall, et al. Comparative microstructures of natural and experimentally produced clay-bearing fault gouges. Pure. Appl. Geophys. 124, 1, 3–30. (1986) [Google Scholar]
  8. F.M. Chester, J.P. Evans, R.L. Biegel. Internal structure and weakening mechanisms of the San Andreas Fault. J. Geophys. Res-Sol. Ea. 98, B1. (1993) [Google Scholar]
  9. C. Marone, C.H. Scholz. Particle-size distribution and microstructures within simulated fault gouge. Int. J. Rock. Mech. Min. 27, 3, A142. (1990) [Google Scholar]
  10. N.G. Geng, X.X. Yao, Y. Chen. Preliminary study on mechanical properties of the fault gouge of five faults in China. ERC. 1, 04, 62–67. 1985 (In Chinese) [Google Scholar]
  11. W.F. Han. Research on major engineering geological problems in the development of the Heishangxia Reach of the Yellow River. Research on major engineering geological problems in the development of the Heishangxia Reach of the Yellow River. (2004) (In Chinese) [Google Scholar]
  12. Q. Klima. Investigation for probabilistic prediction of shear strength properties of clay-rich fault gouge in the Austrian Alps. Eng. Geol. 94, 1-2, 103–121. (2007) [Google Scholar]
  13. P. Lin, R.K. Wang, S.Z. Kang, et al. Research on the Key Problems of Damage, Reinforcement and stability of extremely high arch dam foundation. J. Rock. Mech. Eng. 30, 10, 1945–1958. (2011) (In Chinese) [Google Scholar]
  14. H.M. Zhou, Y.H. Zhang A review of the application of new technology of in-situ test of rock mass in hydraulic complex rock mass engineering. J Yr Sci Res Inst. 37, 04, 1–6. (2020) (In Chinese) [Google Scholar]
  15. H.Y. Qi, Y.B. Cai, Z.F. Liu, et al. Experimental study on deformation modulus of borehole for reconstruction of metamorphic conglomerate in dam foundation of Fengman Hydropower Station. Ne. Water. Resour. H-p. 28, 11, 50–53. (2010) (In Chinese) [Google Scholar]
  16. B. Xiao, D.N. Zhou, Z.H. Min. Relaxation Analysis of the Arch Dam Foundation Rock Masses of Jinping I Hydropower Project. Appl. Mech. Mater. 580-583, 2108–2111. (2014) [Google Scholar]
  17. E.F. Zhao, Y.F. Jiang, L. Foong. Seepage Evolution Model of the Fractured Rock Mass under High Seepage Pressure in Dam Foundation. Adv. Civ. Eng. 2021. (2021) [Google Scholar]

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