Collapse of a liquid-saturated granular column on a horizontal plane

Bougouin, Alexis; Lacaze, Laurent; Bonometti, Thomas

doi:10.1103/physrevfluids.4.124306

Cited by 27 publications

(20 citation statements)

References 43 publications

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“…Entanglement is not the only mechanism that can lead to stable piles; such stable granular columns have been reported in the case of cohesive particles [54] and fluid-saturated particles [55]. In [54] Abramian et al conducted discrete and continuous two-dimensional simulations of the slumping of a column of cohesive particles and observed stable and collapsed regimes.…”

Section: Analogy With Other Stable Granular Assembliesmentioning

confidence: 99%

“…In [54] Abramian et al conducted discrete and continuous two-dimensional simulations of the slumping of a column of cohesive particles and observed stable and collapsed regimes. In [55] Bougouin et al examined the problem of the slumping of a fluid-saturated column of particles. In their study, varying the "column" Bond number, which compares gravity to capillary effects, also leads to stable and collapsed regimes.…”

Section: Analogy With Other Stable Granular Assembliesmentioning

confidence: 99%

“…While in the case of Bougouin et al (Abramian et al) the capillary (cohesive) force plays the role of the stabilizing mechanism, in our study the stabilizing effect comes from the inhibition of particle displacement resulting from the entanglement of the particles with their neighbors. In a future work, we might attempt to design a column Bond number for entangled granular media and carry out a dimensional analysis similar to that of [55] in order to capture the transitions between the observed regimes. As this column Bond number would be the ratio of the gravitational force over the stabilizing force, it would require including a measure of the aforementioned displacement inhibition due to the presence of entangled neighbours.…”

Section: Analogy With Other Stable Granular Assembliesmentioning

confidence: 99%

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Granular avalanches of entangled rigid particles

et al. 2021

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Section: Analogy With Other Stable Granular Assembliesmentioning

confidence: 99%

Section: Analogy With Other Stable Granular Assembliesmentioning

confidence: 99%

Section: Analogy With Other Stable Granular Assembliesmentioning

confidence: 99%

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Granular avalanches of entangled rigid particles

et al. 2021

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“…In this contribution, we are interested in characterising the failing behaviour of cohesive columns of varying cohe-sive properties. While most works on granular columns, including the collapse of cohesive material, concentrate on the run-out behaviour or the deposit shape after the collapse [21][22][23][24][25][26], the present work focuses on the first instant of the failure. The objective is twofold.…”

Section: Introductionmentioning

confidence: 99%

Frictional weakening induced by cohesion: the numerical case of cohesive granular failures

Staron¹,

Duchemin²,

Abramian³

et al. 2022

Preprint

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The failure of 2D numerical cohesive granular steps collapsing under gravity are simulated for a large range of cohesion. Focussing on the cumulative displacement of the grains, and defining a displacement threshold, we establish a sensible criterion for capturing the failure characteristics. We are able to locate the failure in time and to identify the different stages of the destabilisation. We find that the onset of the failure is delayed by increasing cohesion, but its duration becomes shorter. Defining a narrow displacement interval, a well-defined shear band revealing the failure comes out. Solving the equilibrium of the failing block, we are able to make successful predictions for the dependance between failure angle and cohesion, thereby disclosing two distinct frictional behaviour: while friction remains constant at small cohesion, it significantly decreases with cohesive properties at larger cohesion. The results hence reveal two regimes for the behaviour of cohesive granular matter depending on cohesion strength, revealing a cohesion-induced weakening mechanism.

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“…Furthermore, the Stokes number which indicates the relative importance of the grain inertia and fluid viscosity effects, grain/fluid density ratio, and initial aspect ratio considerably influence the collapse process and deposition profile (Bougouin & Lacaze, 2018). Research on wet and saturated granular column collapse events has demonstrate that the deposition profile is highly dependent on the water content, Bond number (Artoni et al, 2013;Gabrieli et al, 2013), Stokes number and initial solid volume fraction (Bougouin et al, 2019). Iverson et al (1997) noted that the results of field investigations, laboratory experiments and theoretical analysis suggested that the fluidization transformation of landslides can be attributed to the transition of Coulomb failure to partial or complete liquefaction, which is influenced by high pore pressures.…”

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confidence: 99%

Study of the Dilatancy/Contraction Mechanism of Landslide Fluidization Behavior Using an Initially Saturated Granular Column Collapse Simulation

Liang

Jiang

2021

Water Resources Research

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Debris flows and landslides are the most frequently occurring geological disasters in mountainous environments (F. C. Dai, et al., 2002;Dowling & Santi, 2014). The solid phase of debris flows and landslides is typically composed of granular materials (Iverson, 1997;Lajeunesse et al., 2005). According to their definitions, debris flows and landslides have considerably different motion behaviors. Debris flows exhibit fluidlike continuous shear deformation, whereas landslide deformation is localized along a shear zone or slip surface (Iverson et al., 1997). However, the motion state of landslides may partially or completely evolve to a state similar to that of the debris flow (Iverson et al., 2015;Yin et al., 2016) under certain conditions because of the complete or partial liquidation of the water-laden solid phase (Iverson & George, 2016). This phenomenon of the motion state transformation driven by the pore fluid pressure can be termed fluidization transformation. The fluidization transformation of landslides leads to the expansion of the effect area and increase in the motion speed. It is necessary to study the transformation mechanism to predict the motion process of landslides and debris flows.To understand the physical processes of unsteady granular flows, dry, immersed, and wet granular column collapse experiments and simulations have been conducted. The dry granular column collapse experiments highlighted that the flow phenomenon, kinematic process and deposition profile are highly dependent on the initial aspect ratio a = H i /L i (Lajeunesse et al., 2005;Lube et al., 2004Lube et al., , 2005 and internal friction angle (Balmforth & Kerswell, 2005), where H i and L i denote the initial height and length of a granular column, respectively. In experimental scenarios, the effect of the ambient fluid can be neglected during the dry granular column collapse process for large granules. However, Roche et al. (2008Roche et al. ( , 2011 experimentally demonstrated that the pore gas pressure that was initially imposed by a vertical air flux through the granular

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Collapse of a liquid-saturated granular column on a horizontal plane

Cited by 27 publications

References 43 publications

Granular avalanches of entangled rigid particles

Granular avalanches of entangled rigid particles

Frictional weakening induced by cohesion: the numerical case of cohesive granular failures

Study of the Dilatancy/Contraction Mechanism of Landslide Fluidization Behavior Using an Initially Saturated Granular Column Collapse Simulation

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