Abstract
Evaluating the failure probability of a slope under the seismic condition during a given exposure time is important for performance-based assessment of slope stability. In this paper, a two-stage method is suggested to study the seismic stability of a slope during a given exposure time. In the first stage, the exceedance probability of the horizontal pseudo-static acceleration is evaluated. In the second stage, the vulnerability curve of the slope, which shows the relationship between the horizontal pseudo-static acceleration and the failure probability of the slope, is established. The failure probability of the slope during a given exposure time is then assessed by combining the exceedance probability curve of the horizontal pseudo-static acceleration and the vulnerability curve of the slope. Examples investigated show that the reliability of a slope under the seismic condition is controlled by multiple slip surfaces. A slope may have different failure probabilities during the same exposure time when it is at different locations because of different levels of ground shaking. Event at the same site, different slopes may have different failure probability because of the difference in factors like slope geometries and geological conditions. The method suggested in this paper can be used to quantify the effect of the above factors on the reliability of a slope.
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This research is substantially supported by the Shanghai Rising-star Program (15QA1403800) and the Natural Science Foundation of China (41672276, 51538009).
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Huang, H.W., Wen, S.C., Zhang, J. et al. Reliability analysis of slope stability under seismic condition during a given exposure time. Landslides 15, 2303–2313 (2018). https://doi.org/10.1007/s10346-018-1050-9
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DOI: https://doi.org/10.1007/s10346-018-1050-9