Static liquefaction mechanisms in loose sand fill slopes

To investigate potential triggering and failure mechanisms of loose fill slopes, two centrifuge model tests were conducted on loose sand with a contractive tendency andhigh liquefaction potential. The behaviour ofloose sand fill slopes subjected to rising groundwater or rainfall was simulated using...

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Bibliographic Details
Published inComputers and geotechnics Vol. 141; p. 104525
Main Authors Ng, Charles W.W., Crous, Petrus A., Zhang, Min, Shakeel, Muhammad
Format Journal Article
LanguageEnglish
Published New York Elsevier Ltd 01.01.2022
Elsevier BV
Subjects
Centrifuge model
Centrifuge modelling
Centrifuges
Failure mechanisms
Finite-element modelling
Flowslides
Groundwater
Gullies
Liquefaction
Mathematical models
Rain
Rainfall
Sand
Shear strength
Slope
Slope stability
Slopes
Soil
Soil investigations
Soil nailing
Soil strength
Static liquefaction
Three dimensional analysis
Soil nailing
Slope stability
Finite-element modelling
Static liquefaction
Centrifuge modelling
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Summary:To investigate potential triggering and failure mechanisms of loose fill slopes, two centrifuge model tests were conducted on loose sand with a contractive tendency andhigh liquefaction potential. The behaviour ofloose sand fill slopes subjected to rising groundwater or rainfall was simulated using a geotechnical centrifuge. Moreover, a three-dimensional back-analysis and parametric study were conducted to investigate the role of soil nails in preventing the triggering of static liquefaction in loose fill slopes. Contrary to the rainfall test where only excessive settlements are observed, arapid, and brittle fluidised flowslide in the slope can be identified whensubjected to rising groundwater. The fluidised flowslide is triggered by a localised drained surface failure in the form of a gully at the crest of the slope. The initial failure at the crest induces the generation of significant excess pore pressures within the slope, causing a significant reduction in effective stress andloss of shear strength due to static liquefaction. For an identical slope, numerical simulations indicate that a fluidised flowslide can be prevented by soil nailing. Soil nailing can prevent the peak shear strength of the soil from being mobilised and limits the excessive strains required to trigger static liquefaction.
ISSN:0266-352X
1873-7633
DOI:10.1016/j.compgeo.2021.104525