A Computationally Efficient Method to Determine the Probability of Rainfall-Triggered Cut Slope Failure Accounting for Upslope Hydrological Conditions

Robson, Ellen; Milledge, David; Utili, Stefano; Dattola, Giuseppe

doi:10.1007/s00603-023-03694-5

A Computationally Efficient Method to Determine the Probability of Rainfall-Triggered Cut Slope Failure Accounting for Upslope Hydrological Conditions

Robson, Ellen; Milledge, David; Utili, Stefano; Dattola, Giuseppe

Authors

Dr Ellen Robson ellen.robson@durham.ac.uk
Post-Doctoral Research Associate

David Milledge

Stefano Utili

Giuseppe Dattola

Abstract

We present a new computationally efficient methodology to estimate the probability of rainfall-induced slope failure based on mechanical probabilistic slope stability analyses coupled with a hydrogeological model of the upslope area. The model accounts for: (1) uncertainty of geotechnical and hydrogeological parameters; (2) rainfall precipitation recorded over a period of time; and (3) the effect of upslope topography. The methodology provides two key outputs: (1) time-varying conditional probability of slope failure; and (2) an estimate of the absolute frequency of slope failure over any time period of interest. The methodology consists of the following steps: first, characterising the uncertainty of the slope geomaterial strength parameters; second, performing limit equilibrium method stability analyses for the realisations of the geomaterial strength parameters required to calculate the slope probability of failure by a Monte Carlo Simulation. The stability analyses are performed for various phreatic surface heights. These phreatic surfaces are then matched to a phreatic surface time series obtained from the 1D Hillslope-Storage Boussinesq model run for the upslope area to generate Factor of Safety (FoS) time series. A time-varying conditional probability of failure and an absolute frequency of slope failure can then be estimated from these FoS time series. We demonstrate this methodology on a road slope cutting in Nepal where geotechnical tests are not readily conducted. We believe this methodology improves the reliability of slope safety estimates where site investigation is not possible. Also, the methodology enables practitioners to avoid making unrealistic assumptions on the hydrological input. Finally, we find that the time-varying failure probability shows marked variations over time as a result of the monsoon wet–dry weather.

Citation

Robson, E., Milledge, D., Utili, S., & Dattola, G. (2024). A Computationally Efficient Method to Determine the Probability of Rainfall-Triggered Cut Slope Failure Accounting for Upslope Hydrological Conditions. Rock Mechanics and Rock Engineering, 57(4), 2421-2443. https://doi.org/10.1007/s00603-023-03694-5

Journal Article Type	Article
Acceptance Date	Nov 20, 2023
Online Publication Date	Dec 24, 2023
Publication Date	Apr 1, 2024
Deposit Date	Jan 9, 2024
Publicly Available Date	Jan 9, 2024
Journal	Rock Mechanics and Rock Engineering
Print ISSN	0723-2632
Electronic ISSN	1434-453X
Publisher	Springer
Peer Reviewed	Peer Reviewed
Volume	57
Issue	4
Pages	2421-2443
DOI	https://doi.org/10.1007/s00603-023-03694-5
Keywords	Slope stability, Limit equilibrium method, Probabilistic stability analyses, Nepal, Hillslope-Storage Boussinesq, Monte Carlo simulation
Public URL	https://durham-repository.worktribe.com/output/2116821

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