A Comparative Study of the Seismic Performances and Failure Mechanisms of Slopes Using Dynamic Centrifuge Modeling

Hualin Cheng; Jiamin Zhou; Zhiyi Chen; Yu Huang

doi:10.1007/s12583-021-1481-4

Journal of Earth Science ›› 2021, Vol. 32 ›› Issue (5) : 1166 -1173. DOI: 10.1007/s12583-021-1481-4

Special Issue on Geo-Disasters

A Comparative Study of the Seismic Performances and Failure Mechanisms of Slopes Using Dynamic Centrifuge Modeling

Author information +

History +

PDF

Abstract

In this study, dynamic centrifuge model tests were performed for sand slopes under different earthquake ground motions and slope angle to characterize the seismic performance of slopes. Four groups of tests under varying seismic input amplitude were conducted. Under the action of increasing earthquake intensity, the rigidity of the soil decreases and the damping ratio increases, both of the dynamic response and the predominant period of slopes are increased. Three types of seismic waves with the same seismic intensity were applied in the model tests. It shows that the variability in the ground motion leads to the acceleration response spectra of the slopes being completely different and the Northridge seismic wave with low-frequency component is closest to the predominant period of the slope model. In addition, the effect of slope angle on the seismic performance of slopes were also clarified. The results reveal how the slope angle affects the acceleration recorded on the ground surface of the slope, both in terms of the peak ground-motion acceleration (PGA) amplification factor and the predominant period. Finally, the permanent displacement of the model slopes under different earthquake intensities were further analyzed. Based on the nonlinear growth of the permanent displacement of the slope, the test results demonstrated the failure process of the slope, which can further provide a basis for theperformance-based seismic design of slopes.

Keywords

slope failure / dynamic centrifuge modeling / seismic performance / permanent displacement

Cite this article

Download citation ▾

Hualin Cheng, Jiamin Zhou, Zhiyi Chen, Yu Huang. A Comparative Study of the Seismic Performances and Failure Mechanisms of Slopes Using Dynamic Centrifuge Modeling. Journal of Earth Science, 2021, 32(5): 1166-1173 DOI:10.1007/s12583-021-1481-4

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Bao Y J, Huang Y, Liu G R, . SPH Simulation of High-Volume Rapid Landslides Triggered by Earthquakes Based on a Unified Constitutive Model. Part II: Solid-Liquid-Like Phase Transition and Flow-Like Landslides. International Journal of Computational Methods, 2020, 17(4): 1850149

[2]	Gao Y, Li Z, Sun D A, . A Simple Method for Predicting the Hydraulic Properties of Unsaturated Soils with Different Void Ratios. Soil and Tillage Research, 2021, 209: 104913

[3]	Gorum T, Fan X M, van Westen C J, . Distribution Pattern of Earthquake-Induced Landslides Triggered by the 12 May 2008 Wenchuan Earthquake. Geomorphology, 2011, 133 3/4 152-167.

[4]	Havenith H B, Vanini M, Jongmans D, . Initiation of Earthquake-Induced Slope Failure: Influence of Topographical and Other Site Specific Amplification Effects. Journal of Seismology, 2003, 7(3): 397-412.

[5]	He J X, Qi S W, Wang Y S, . Seismic Response of the Lengzhuguan Slope Caused by Topographic and Geological Effects. Engineering Geology, 2020, 265 105431

[6]	Hong Y S, Chen R H, Wu C S, . Shaking Table Tests and Stability Analysis of Steep Nailed Slopes. Canadian Geotechnical Journal, 2005, 42(5): 1264-1279.

[7]	Huang Y, Jiang X M. Field-Observed Phenomena of Seismic Liquefaction and Subsidence during the 2008 Wenchuan Earthquake in China. Natural Hazards, 2010, 54(3): 839-850.

[8]	Karray M, Hussien M N, Delisle M C, . Framework to Assess Pseudo-Static Approach for Seismic Stability of Clayey Slopes. Canadian Geotechnical Journal, 2018, 55(12): 1860-1876.

[9]	Ko H Y. Craig W H, James R G, Schofield A N. Summary of the State-of-Art in Centrifuge Model Testing. Centrifuge in Soil Mechanics, 1988, Rotterdam, Netherlands: Balkema, 11-18.

[10]	Krishna A M, Latha G M. Seismic Response of Wrap-Faced Reinforced Soil-Retaining Wall Models Using Shaking Table Tests. Geosynthetics International, 2007, 14(6): 355-364.

[11]	Lee M G, Ha J G, Cho H I, . Improved Performance-Based Seismic Coefficient for Gravity-Type Quay Walls Based on Centrifuge Test Results. Acta Geotechnica, 2021, 16(4): 1187-1204.

[12]	Lenti L, Martino S. The Interaction of Seismic Waves with Step-Like Slopes and Its Influence on Landslide Movements. Engineering Geology, 2012, 126: 19-36.

[13]	Liang T, Knappett J A, Leung A K, . Modelling the Seismic Performance of Root-Reinforced Slopes Using the Finite-Element Method. Géotechnique, 2020, 70(5): 375-391.

[14]	Macedo J, Candia G. Performance-Based Assessment of the Seismic Pseudo-Static Coefficient Used in Slope Stability Analysis. Soil Dynamics and Earthquake Engineering, 2020, 133: 106109

[15]	Nakajima S, Abe K, Shinoda M, . Dynamic Centrifuge Model Tests and Material Point Method Analysis of the Impact Force of a Sliding Soil Mass Caused by Earthquake-Induced Slope Failure. Soils and Foundations, 2019, 59(6): 1813-1829.

[16]	Sepúlveda S A, Murphy W, Jibson R W, . Seismically Induced Rock Slope Failures Resulting from Topographic Amplification of Strong Ground Motions: The Case of Pacoima Canyon, California. Engineering Geology, 2005, 80(3/4): 336-348.

[17]	Shinoda M, Watanabe K, Sanagawa T, . Dynamic Behavior of Slope Models with Various Slope Inclinations. Soils and Foundations, 2015, 55(1): 127-142.

[18]	Song D Q, Che A L, Chen Z, . Seismic Stability of a Rock Slope with Discontinuities under Rapid Water Drawdown and Earthquakes in Large-Scale Shaking Table Tests. Engineering Geology, 2018, 245 153-168.

[19]	Srilatha N, Madhavi Latha G, Puttappa C G. Effect of Frequency on Seismic Response of Reinforced Soil Slopes in Shaking Table Tests. Geotextiles and Geomembranes, 2013, 36: 27-32.

[20]	Stewart D P, Chen Y R, Kutter B L. Experience with the Use of Methylcellulose as a Viscous Pore Fluid in Centrifuge Models. Geotechnical Testing Journal, 1998, 21(4): 365-369.

[21]	Take W A, Bolton M D, Wong P C P, . Evaluation of Landslide Triggering Mechanisms in Model Fill Slopes. Landslides, 2004, 1(3): 173-184.

[22]	Wang K L, Lin M L. Initiation and Displacement of Landslide Induced by Earthquake—A Study of Shaking Table Model Slope Test. Engineering Geology, 2011, 122(1/2): 106-114.

[23]	Wang L P, Zhang G. Centrifuge Model Test Study on Pile Reinforcement Behavior of Cohesive Soil Slopes under Earthquake Conditions. Landslides, 2014, 11(2): 213-223.

[24]	Wang W, Chen H, Xu A H, . Analysis of the Disaster Characteristics and Emergency Response of the Jiuzhaigou Earthquake. Natural Hazards and Earth System Sciences, 2018, 18(6): 1771-1783.

[25]	Xiong M, Huang Y. Novel Perspective of Seismic Performance-Based Evaluation and Design for Resilient and Sustainable Slope Engineering. Engineering Geology, 2019, 262: 105356

[26]	Xiong Y L, Ye G L, Xie Y, . A Unified Constitutive Model for Unsaturated Soil under Monotonic and Cyclic Loading. Acta Geotechnica, 2019, 14(2): 313-328.

[27]	Xiong Y L, Ye G L, Zhu H H, . Thermo-Elastoplastic Constitutive Model for Unsaturated Soils. Acta Geotechnica, 2016, 11(6): 1287-1302.

[28]	Xu C, Xu X W, Shyu J B H. Database and Spatial Distribution of Landslides Triggered by the Lushan, China M _w6.6 Earthquake of 20 April 2013. Geomorphology, 2015, 248 77-92.

[29]	Xu C, Xu X W, Yu G H. Landslides Triggered by Slipping-Fault-Generated Earthquake on a Plateau: An Example of the 14 April 2010, Ms7.1, Yushu, China Earthquake. Landslides, 2013, 10(4): 421-431.

[30]	Yu Y Z, Deng L J, Sun X, . Centrifuge Modeling of a Dry Sandy Slope Response to Earthquake Loading. Bulletin of Earthquake Engineering, 2008, 6(3): 447-461.

[31]	Zhang Z L, Wang T, Wu S R, . Seismic Performance of Loess-Mudstone Slope in Tianshui-Centrifuge Model Tests and Numerical Analysis. Engineering Geology, 2017, 222: 225-235.

[32]	Zhang Z Z, Fleurisson J A, Pellet F. The Effects of Slope Topography on Acceleration Amplification and Interaction between Slope Topography and Seismic Input Motion. Soil Dynamics and Earthquake Engineering, 2018, 113: 420-431.

[33]	Zheng H, Wang D, Behringer R P. Experimental Study on Granular Biaxial Test Based on Photoelastic Technique. Engineering Geology, 2019, 260 105208