Identification of mechanisms for landslide type initiation of debris flows

Klubertanz, G.; Laloui, Lyesse; Vulliet, L.

doi:10.1016/j.enggeo.2009.06.007

Cited by 38 publications

(23 citation statements)

References 30 publications

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“…Klubertanz et al 2009;Jakob and Hungr 2005;Iverson 1997). However, it is clear that occurrence of a debris flow requires large volumes of sediment to be available, either on slopes or in a stream channel, and steep slopes to allow rainfall and/or streamflow of sufficient intensity to mobilise the sediment.…”

Section: Debris Flowsmentioning

confidence: 94%

Identification of alluvial fans susceptible to debris-flow hazards

Welsh¹,

Davies

2010

Landslides

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Identification of alluvial fans susceptible to debris-flow hazardsAbstract We describe and test a method for identifying alluvial fans likely to be affected by debris flows. It is based on identifying catchment parameters by geographical information system interrogation of a digital elevation model, using the Melton ratio as the discriminating parameter. The method was calibrated using data from debris-flow-generating catchments in Coromandel and the adjacent Kaimai Ranges, North Island, NZ, and tested against data from the rest of New Zealand. The procedure is remarkably (but not completely) reliable for identifying debris-flow-capable catchments, and thus fans, across the wide range of climates and lithologies in New Zealand mountains. A case study illustrates the potential of the method for avoiding future hazards and emphasises the need for a precautionary approach when field investigations do not detect evidence for past debris flows.

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Section: Debris Flowsmentioning

confidence: 94%

Identification of alluvial fans susceptible to debris-flow hazards

Welsh¹,

Davies

2010

Landslides

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“…It is shown that the model (21) is applicable to both initially and fully developed plastic deformation of granular materials with drained or undrained conditions [41,43]. It will reduce to the original one (16) when the void ratio e is equal to the critical value e crt from (22) and (23). It means, for same material, same constants c 1 $ c 4 will be obtained for the original and extended models in the case of e ¼ e ecrt .…”

Section: Introductionmentioning

confidence: 78%

“…Numerical analysis plays an important role to obtain this information, where a competent constitutive model for debris materials is required. The main factors influencing the initiation of debris flow are, among others, the topography, material parameters, water and the initial stress state in the affected slope [22]. Earth slopes with inclinations ranging from 26 to 45 have been generally identified as most prone to debris flow initiation [40].…”

Section: Introductionmentioning

confidence: 99%

A hypoplastic constitutive model for debris materials

Guo¹,

Peng²,

Wu³

et al. 2016

Acta Geotech.

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Debris flow is a very common and destructive natural hazard in mountainous regions. Pore water pressure is the major triggering factor in the initiation of debris flow. Excessive pore water pressure is also observed during the runout and deposition of debris flow. Debris materials are normally treated as solid particle-viscous fluid mixture in the constitutive modeling. A suitable constitutive model which can capture the solid-like and fluid-like behavior of solid-fluid mixture should have the capability to describe the developing of pore water pressure (or effective stresses) in the initiation stage and determine the residual effective stresses exactly. In this paper, a constitutive model of debris materials is developed based on a framework where a static portion for the frictional behavior and a dynamic portion for the viscous behavior are combined. The frictional behavior is described by a hypoplastic model with critical state for granular materials. The model performance is demonstrated by simulating undrained simple shear tests of saturated sand, which are particularly relevant for the initiation of debris flows. The partial and full liquefaction of saturated granular material under undrained condition is reproduced by the hypoplastic model. The viscous behavior is described by the tensor form of a modified Bagnold's theory for solid-fluid suspension, in which the drag force of the interstitial fluid and the particle collisions are considered. The complete model by combining the static and dynamic parts is used to simulate two annular shear tests. The predicted residual strength in the quasi-static stage combined with the stresses in the flowing stage agrees well with the experimental data. The non-quadratic dependence between the stresses and the shear rate in the slow shear stage for the relatively dense specimens is captured.

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“…The hydromechanical behaviour of the involved volcanic ash has been characterised by means of a comprehensive experimental laboratory testing program [17,18], thus enabling the use of a physically-based model for seepage and slope stability analyses. Compared to more detailed geomechanical models at the local slope scale [19][20][21], the model described hereafter allows a pragmatic, general exploration of the effects of a series of wet season rainfall events on slope stability as a function of soil hydraulic and strength properties, as well as slope inclination.…”

Section: Physically-based Approach For the Preliminary Establishment mentioning

confidence: 99%

Early warning thresholds for partially saturated slopes in volcanic ashes

Eichenberger

Ferrari

Laloui

2013

Computers and Geotechnics

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a b s t r a c tRainfall-induced landslides in steep soil slopes of volcanic origin are a major threat to human lives and infrastructure. In the context of constructing early warning systems in regions where extensive data on landslide occurrences and associated rainfall are inexistent, physically-based tools offer the possibility to establish thresholds for measurable field quantities. In this paper, a combined finite element infinite slope model is presented to study the transient hydraulic response of volcanic ash slopes to a series of rainfall events and to estimate seasonal safety factors. Furthermore, analytical considerations of partially saturated infinite slopes are made to define capillary stress thresholds for a landslide early warning system.

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Identification of mechanisms for landslide type initiation of debris flows

Cited by 38 publications

References 30 publications

Identification of alluvial fans susceptible to debris-flow hazards

Identification of alluvial fans susceptible to debris-flow hazards

A hypoplastic constitutive model for debris materials

Early warning thresholds for partially saturated slopes in volcanic ashes

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