Three-dimensional and real-scale modeling of flow regimes in dense snow avalanches

With ongoing global warming, snow avalanche dynamics may change as snow cohesion and friction strongly depend on temperature. In the field, a diversity of avalanche flow regimes has been reported including fast, sheared flows and slow plugs. While the significant role of cohesion and friction has been recognized, it is unclear how these mechanical properties affect avalanche flow regimes. Here, we model granular avalanches on a periodic inclined plane, using the distinct element method to better understand and quantify how inter-particle cohesion and ground friction influences avalanche velocity profiles. The cohesion between particles is modeled through bonds that can subsequently break and form, thus representing fragmentation and aggregation potentials, respectively. The implemented model shows a good ability to reproduce the various flow regimes and transitions as observed in nature: for low cohesion, highly sheared and fast flows are obtained while slow plugs form above a critical cohesion value and for lower ground frictions. Simulated velocity profiles are successfully compared to experimental measurements from the real-scale test site of Vallée de la Sionne in Switzerland. Even though the model represents a strong simplification of the reality, it offers a solid basis for further investigation of relevant processes happening in snow avalanches, such as segregation, erosion and entrainment, with strong impacts on avalanche dynamics research, especially in a climate change context.

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“…[ 14 ] and simulated by Li et al . [ 66 ] was not modeled here. Fig 6i shows aggregates due to breakage only.…”

Section: Discussionmentioning

confidence: 99%

Numerical investigation of the effect of cohesion and ground friction on snow avalanches flow regimes

Ligneau

Sovilla²,

Gaume

2022

PLoS ONE

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“…This study aims to quantify the amount of snow caught in forests and explore the mechanism of the detrainment, with comprehensive consideration of different avalanche features and forest configurations. We use a three-dimensional material point method (3D MPM), by which the fractures, collisions, and large deformations involved in snow avalanches can be well captured (Gaume et al, 2018(Gaume et al, , 2019Li et al, 2020Li et al, , 2021. More importantly, individual trees and their interactions with snow avalanches can be explicitly modelled without relying on empirical laws.…”

Section: Introductionmentioning

confidence: 99%

Detrainment and braking of snow avalanches interacting with forests

Védrine

Gaume

2022

Nat. Hazards Earth Syst. Sci.

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Abstract. Mountain forests provide natural protection against avalanches. They can both prevent avalanche formation in release zones and reduce avalanche mobility in runout areas. Although the braking effect of forests has been previously explored through global statistical analyses on documented avalanches, little is known about the mechanism of snow detrainment in forests for small and medium avalanches. In this study, we investigate the detrainment and braking of snow avalanches in forested terrain, by performing three-dimensional simulations using the material point method (MPM) and a large-strain elastoplastic snow constitutive model based on critical state soil mechanics. First, the snow internal friction is evaluated using existing field measurements based on the detrainment mass, showing the feasibility of the numerical framework and offering a reference case for further exploration of different snow types. Then, we systematically investigate the influence of snow properties and forest parameters on avalanche characteristics. Our results suggest that for both the cold and warm snow parameterized in our simulations, the detrainment mass decreases with the square of the avalanche front velocity before it reaches a plateau value. Furthermore, the detrainment mass significantly depends on snow properties. It can be as much as 10 times larger for warm snow compared to cold snow. By examining the effect of forest configurations, it is found that forest density and tree diameter have cubic and square relations with the detrainment mass, respectively. The outcomes of this study may contribute to the development of improved formulations of avalanche–forest interaction models in popular operational simulation tools and thus improve hazard assessment for alpine geophysical mass flows in forested terrain.

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“…Moreover, the 2D setting may also prevent modeling of some practical problems with realistic topography. 30,31 Therefore, a true 3D multiscale modeling framework is highly desirable. Second, though the extension from 2D to 3D is conceptually straightforward, it remains challenging from an implementation perspective.…”

Section: Introductionmentioning

confidence: 99%

“…To capture the influence of loading conditions on the failure behavior, 3D modeling is required. Moreover, the 2D setting may also prevent modeling of some practical problems with realistic topography 30,31 . Therefore, a true 3D multiscale modeling framework is highly desirable.…”

Section: Introductionmentioning

confidence: 99%

Scalable three‐dimensional hybrid continuum‐discrete multiscale modeling of granular media

Liang

Zhao

et al. 2022

Numerical Meth Engineering

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This study presents a scalable three‐dimensional (3D) multiscale framework for continuum‐discrete modeling of granular materials. The proposed framework features rigorous coupling of a continuum‐based material point method (MPM) and a discrete approach discrete element method (DEM) to enable cross‐scale modeling of boundary value problems pertaining to granular media. It employs MPM to solve the governing equations of a macroscopic continuum domain for a boundary value problem that may undergo large deformation. The required loading‐path‐dependent constitutive responses at each material point of the MPM are provided by a DEM solution based on grain‐scale contact‐based discrete simulations that receive macroscopic information at the specific material point as boundary conditions. This hierarchical coupling enables direct dialogs between the macro and micro scales of granular media while fully harnessing the predictive advantages of both MPM and DEM at the two scales. An effective, scalable parallel scheme is further developed, based on the flat message passing interface (MPI) model, to address the computational cost of the proposed framework for 3D large‐scale simulations. We demonstrate that the proposed parallel scheme may offer up to 32X and 40X speedup in strong and weak scaling tests, respectively, significantly empowering the numerical performance and predictive capability of the proposed framework. The 3D parallelized multiscale framework is validated by an element test and a column collapse problem, before being applied to simulate the intrusion of a solid object. The multiscale simulation successfully captures the characteristic response of intrusion as postulated by the modified Archimedes' law theory. The progressive development of the stagnant zone during the intrusion is further examined from a cross‐scale perspective.

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Three-dimensional and real-scale modeling of flow regimes in dense snow avalanches

Cited by 32 publications

References 64 publications

Numerical investigation of the effect of cohesion and ground friction on snow avalanches flow regimes

Numerical investigation of the effect of cohesion and ground friction on snow avalanches flow regimes

Detrainment and braking of snow avalanches interacting with forests

Scalable three‐dimensional hybrid continuum‐discrete multiscale modeling of granular media

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