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Analysis on Landslide Process and Evolution of Contact Network of Cohensionless Soil Slope

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ã€Authorã€‘ JIANG Lian;LIU Enlong;TIAN Jianqiu;JIANG Xiaoqiong;State Key Laboratory of Hydraulics and Mountain River Engineering, Sichuan University;College of Water Resources and Hydropower, Sichuan University;

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ã€Abstractã€‘ Based on the discrete element method, the geometrical model of slope was established here to investigate the slope failure during the landslide process by reducing the bond strength at all contacts between particles to be zero. By recording the slope failure configurations on different time steps, both slope failure on macro-scale and the slope failure from a complex network perspective, i.e., average degree, average path length and network density, of the slope top, the middle of the slope and slope toe were analyzed in detail. The result demonstrates that a) during the landslide process, the soil close to slope surface moves along downward slope. The displacements of particles will be larger when they are closer to the slope surface; b) the post-failure slope surface passes through the centre of the initial slope surface, and the post-failure inclination is slightly smaller than the peak internal friction angle of the material; c) the number of contacts between particles of the top/middle/toe of slope are all decrease at the beginning of slope sliding, which leads to the reducation of shear strength and causes landslide easily to occur; d) with the increase of time steps, the slope top of the average shortest path length decreases and the slope toe of the average shortest path length increases, which causes the slope top particles to exchange information more easily than those of slope toe and; e) with the increase of time steps, the contact networks of become denser, and the contact networks of slope toe becomes sparser, which can explain the reason that the soil at the slope toe after slope failure becomes looser.æ›´å¤š è¿˜åŽŸ