Response of a residual soil slope to rainfall

Rahardjo, Harianto; Lee, T T; Leong, Eng Choon; Rezaur, R. B.

doi:10.1139/t04-101

Cited by 229 publications

(97 citation statements)

References 15 publications

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“…7b), suggests that the shape of the measured infiltration capacity decay curve, and particularly the i f value measured is incorrect (the i f value would be expected to be too high). Rahardjo et al (2005) note that the initial and final volumetric content near the toe of the slope always appeared to be higher than those at the crest, suggesting that some water that infiltrates near the crest of the slope may then flow downslope, parallel to the slope surface, thus resulting in higher water content and lower suction near the toe of the slope than near the crest. The same i f value was therefore adopted for both analyses.…”

Section: Infiltration Capacity Decay Curvesmentioning

confidence: 94%

“…2 we note that the key assumptions of the Mein-Larson model are that the minimum infiltration capacity of the soil is equal to the saturated permeability and that run-off will not occur unless the rainfall intensity exceeds the saturated permeability of the soil. Rahardjo et al (2005) report measurements of the infiltration response of a residual soil slope subjected to artificial rainfall events. The instrumented slope comprised a 1.5 m deep layer of orange silty clay with a saturated permeability of 5.18 · 10 -6 m/s, overlying a 4-5 m deep layer of purple clayey silt with K s = 1.67 · 10 -7 m/s.…”

Section: Mein-larson Modelmentioning

confidence: 99%

“…7a and b. Rahardjo et al (2005) report values for K s and R i which were used in the analysis. The value of i f was taken directly from measured field data for the 47 mm/h rainfall event shown in Fig.…”

Section: Infiltration Capacity Decay Curvesmentioning

confidence: 99%

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Effect of Rainfall Intensity on Infiltration into Partly Saturated Slopes

Xue

Gavin

2007

Geotech Geol Eng

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This paper describes the development of a model to analyse the rate of infiltration and run-off experienced by a partly saturated soil slope during rainfall. The paper first reviews some of the most popular infiltration models used in geotechnical analysis, and highlights some of the problems associated with their application. One particular model, the Horton Equation is extended to include rainfall intensity directly in its formulation. The new model is shown to predict infiltration responses, which agree with field measurements. In the final section the influence of the rainfall intensity and pattern of rainfall (variation of rainfall intensity) on the infiltration response of a soil is investigated using the new model.

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Section: Infiltration Capacity Decay Curvesmentioning

confidence: 94%

Section: Mein-larson Modelmentioning

confidence: 99%

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Effect of Rainfall Intensity on Infiltration into Partly Saturated Slopes

Xue

Gavin

2007

Geotech Geol Eng

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“…perched water table) at the soil-bedrock interface. Several researchers (McNamara et al, 2005;Rahardjo et al, 2005;D'Odorico et al, 2005) have shown that vertical flow in the unsaturated soil zone is reduced when the infiltration front meets a less permeable layer (for example, the bedrock layer). Under this condition, the infiltrating rainwater collects at the less permeable soil layer, inducing rapid increases of pore-water pressure and unsaturated hydraulic conductivity (according to the relationship between matric suction head and unsaturated hydraulic conductivity).…”

Section: The Hydrological Modelmentioning

confidence: 99%

Modelling shallow landslide susceptibility by means of a subsurface flow path connectivity index and estimates of soil depth spatial distribution

Lanni

Borga

Rigon

et al. 2012

Hydrol. Earth Syst. Sci.

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Abstract. Topographic index-based hydrological models have gained wide use to describe the hydrological control on the triggering of rainfall-induced shallow landslides at the catchment scale. A common assumption in these models is that a spatially continuous water table occurs simultaneously across the catchment. However, during a rainfall event isolated patches of subsurface saturation form above an impeding layer and their hydrological connectivity is a necessary condition for lateral flow initiation at a point on the hillslope.Here, a new hydrological model is presented, which allows us to account for the concept of hydrological connectivity while keeping the simplicity of the topographic index approach. A dynamic topographic index is used to describe the transient lateral flow that is established at a hillslope element when the rainfall amount exceeds a threshold value allowing for (a) development of a perched water table above an impeding layer, and (b) hydrological connectivity between the hillslope element and its own upslope contributing area. A spatially variable soil depth is the main control of hydrological connectivity in the model. The hydrological model is coupled with the infinite slope stability model and with a scaling model for the rainfall frequency-duration relationship to determine the return period of the critical rainfall needed to cause instability on three catchments located in the Italian Alps, where a survey of soil depth spatial distribution is available. The model is compared with a quasi-dynamic model in which the dynamic nature of the hydrological connectivity is neglected. The results show a better performance of the new model in predicting observed shallow landslides, implying that soil depth spatial variability and connectivity bear a significant control on shallow landsliding.

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“…Wei in a case study of the Bukit Batok landslides in Singapore found that the failure occurred after a period of heavy rainfall and there was no rainfall at the time of failure [11]. Antecedent rainfall, initial pore-water pressures prior to a signi cant rainfall event, and the magnitude of the rainfall event play a crucial role in the development of the worst pore-water pressure condition in a slope [12].…”

Section: Introductionmentioning

confidence: 99%

Antecedent rainfall induced shallow landslide-A case study of Yunnan landslide, China

et al. 2017

Scientia Iranica

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Abstract. We present a case study of antecedent rainfall induced failure of engineering slope. The impacts of pore-water pressure, pore-water pressure increment, water content, and the factor of safety are investigated by numerical models for an actual slope in Yunnan, China. The results indicate that antecedent rainfall plays an important role in the stability of the slope. The model reasonably explains the time lag between the occurrences of rainfall and landslides. Pore-water pressures signi cantly change at the upper layer of redclay slope; the occurrence of cracks at the top of the slope agrees with the eld observations before landslide. The saturated zone of the slope gradually expands from the top to bottom of the slope; the major reason for landslide is that the surface stagnant water, after rainfall, gradually in ltrates into the weathered gneiss rock, resulting in decrease in the strength of weathered gneiss rock. Then, the weight of the later rainfall leads to landslide of the slope. The factor of safety of the slope is evaluated by the modi ed limit equilibrium methods. It is shown that the actual failure occurs when the calculated factor of safety approaches its minimum, i.e., 0.97. The landslide is characterized by shallow landslides.

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Response of a residual soil slope to rainfall

Cited by 229 publications

References 15 publications

Effect of Rainfall Intensity on Infiltration into Partly Saturated Slopes

Effect of Rainfall Intensity on Infiltration into Partly Saturated Slopes

Modelling shallow landslide susceptibility by means of a subsurface flow path connectivity index and estimates of soil depth spatial distribution

Antecedent rainfall induced shallow landslide-A case study of Yunnan landslide, China

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