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Influence of slab depth spatial variability on skier-triggering probability and avalanche size

Published online by Cambridge University Press:  18 January 2024

Francis Meloche*
Affiliation:
Laboratoire de Géomorphologie et de Gestion des Risques en Montagnes (LGGRM), Département de Biologie, Chimie et Géographie, Université du Québec à, Rimouski, Canada Center for Nordic Studies, Université Laval, Québec, Canada WSL Institute for Snow and Avalanche Research SLF, CH-7260 Davos Dorf, Switzerland Climate Change, Extremes, and Natural Hazards in Alpine Regions Research Center CERC, CH-7260 Davos Dorf, Switzerland
Louis Guillet
Affiliation:
Univ. Grenoble Alpes, Inria CNRS, Grenoble, France
Francis Gauthier
Affiliation:
Laboratoire de Géomorphologie et de Gestion des Risques en Montagnes (LGGRM), Département de Biologie, Chimie et Géographie, Université du Québec à, Rimouski, Canada Center for Nordic Studies, Université Laval, Québec, Canada
Alexandre Langlois
Affiliation:
Center for Nordic Studies, Université Laval, Québec, Canada Groupe de Recherche Interdisciplinaire en Milieux Polaire (GRIMP), Département de Géomatique, Université de Sherbrooke, Sherbrooke, Canada
Johan Gaume
Affiliation:
WSL Institute for Snow and Avalanche Research SLF, CH-7260 Davos Dorf, Switzerland Climate Change, Extremes, and Natural Hazards in Alpine Regions Research Center CERC, CH-7260 Davos Dorf, Switzerland Institute for Geotechnical Engineering, ETH Zürich, CH-8093 Zürich, Switzerland
*
Corresponding author: Francis Meloche; Email: [email protected]
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Abstract

Spatial variability of snowpack properties adds uncertainty in the evaluation of avalanche hazard. We propose a combined mechanical–statistical approach to study how spatial variation of slab depth affects the skier-triggering probability and possible release size. First, we generate multiple slab depth maps on a plane fictional slope based on Gaussian Random Fields (GRF) for a specific set of mean, variance and correlation length. For each GRF, we derive analytically the Skier Propagation Index (SPI). We then simulate multiple skier tracks and computed the probability based on the number of skier hits where SPI is below 1. Finally, we use a depth-averaged material point method to evaluate the possible avalanche size for given slab depth variations. The results of this analysis show that large correlation lengths and small variances lead to a lower probability of skier-triggering as it reduces the size and the number of areas with low slab depth. Then, we show the effect of skiing style and skier group size on skier-triggering probability. Spatial variability also affects the possible avalanche size by adding stress fluctuation causing early or late tensile failure. Finally, we demonstrate with our models the well-known relationship between the probability and the size in avalanche forecasting.

Type
Article
Creative Commons
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This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2024. Published by Cambridge University Press on behalf of International Glaciological Society

Introduction

Avalanche hazard

Snow avalanches represent a natural hazard for infrastructure and backcountry recreationists across mountainous areas all across the world (Stethem and others, Reference Stethem2003). Snow avalanches can be divided into different types from wet or dry avalanches and also loose-snow or slab avalanches (Schweizer and others, Reference Schweizer, Jamieson and Schneebeli2003). However, dry-snow slab avalanches are the most destructive type and also very difficult to predict (Techel and others, Reference Techel2016). Such an avalanche releases from the failure of a porous weak layer buried below a cohesive snow slab. The initiation of the failure can be induced by a skier, new snow or explosives. If the size of the failed zone in the weak layer – or crack – exceeds a critical size, the crack may self-propagate across the slope possibly leading to the release and sliding of the snow slab (Schweizer and others, Reference Schweizer, Reuter, van Herwijnen and Gaume2016). Statham and others (Reference Statham2018) proposed a conceptual model to better predict the avalanche hazard for practitioners and backcountry recreationists. This conceptual model consists of two main components: the likelihood of an avalanche and the avalanche release size. The combination of these two components gives the avalanche hazard in North America (Statham and others, Reference Statham2018). The terminology is slightly different in Europe which is based on three components: the probability of avalanche release, the frequency of these triggering spots and the avalanche size (Techel and others, Reference Techel, Karsten and Schweizer2020). Practitioners and forecasters use mostly snow stability tests to gain information on the probability of triggering an avalanche, both by a skier or naturally. Repeated tests at numerous locations help them to gain information on the spatial distribution of the instability (Schweizer and others, Reference Schweizer, Kronholm, Jamieson and Birkeland2008). However, the sparse and punctual nature of available observations on snowpack properties makes the forecasting of dry snow slab avalanches difficult (Hägeli and McClung, Reference Hägeli and McClung2004). The second main component of the avalanche hazard is the avalanche release size. Forecasters try to estimate the possible avalanche size by estimating the slab depth and the slab-weak layer propagation propensity. Studies have shown that these properties are highly variable in space (Schweizer and others, Reference Schweizer, Kronholm, Jamieson and Birkeland2008), which makes it even more difficult to predict. The snow spatial variability at different scales also adds complexity to this difficult task by adding uncertainty on whether the properties measured on the field are representatives or not of the slab and weak layer system (Schweizer and others, Reference Schweizer, Kronholm, Jamieson and Birkeland2008). At a smaller scale, the decision-making in avalanche terrain such as the task of up-hill and downhill route finding is very complex partly due to the spatial variability of snow.

Spatial variability of snow

The subject of the spatial variation of snow mechanical properties is nothing new in the science community. Conway and Abrahamson (Reference Conway and Abrahamson1984) has made several measurements of a weak layer shear strength along an avalanche fracture line. They highlight these so-called deficit zones where the weak layer shear strength was significantly lower than surrounding areas along the fracture line. The idea of weak zones or weak spots initiated numerous studies over the last two decades (Schweizer and others, Reference Schweizer, Kronholm, Jamieson and Birkeland2008). New instruments like the high-resolution snow penetrometer called SnowMicroPen (SMP) can measure with great accuracy the snow mechanical properties of both the slab and the weak layer (Johnson and Schneebeli, Reference Johnson and Schneebeli1999; Löwe and van Herwijnen, Reference Löwe and van Herwijnen2012; Proksch and others, Reference Proksch, Löwe and Schneebeli2015; Reuter and others, Reference Reuter, Proksch, Löwe, Van Herwijnen and Schweizer2019). The SMP enabled fast sampling of the snow mechanical properties over several locations on an avalanche-prone slope (Landry and others, Reference Landry2004; Kronholm, Reference Kronholm2004; Feick and others, Reference Feick, Kronholm and Schweizer2007; Lutz and others, Reference Lutz, Birkeland, Kronholm, Hansen and Aspinall2007; Bellaire and Schweizer, Reference Bellaire and Schweizer2011; Lutz and Birkeland, Reference Lutz and Birkeland2011; Reuter and others, Reference Reuter, Richter and Schweizer2016). These studies focused mainly on the weak layer properties, thickness and strength, and they used the variogram analysis to estimate the spatial pattern of the weak layer mechanical properties. They reported correlation distances ranging from 1 to 15 m with a spatial sampling extent of around 20 and 40 m. The correlation distances were nearly half of the extent and this could bias the estimation of the correlation length (Skøien and Blöschl, Reference Skøien and Blöschl2006; Kronholm and Birkeland, Reference Kronholm and Birkeland2007). Reuter and others (Reference Reuter, Richter and Schweizer2016) used the same sampling density but with a spatial extent of nearly 500 m, and reported correlation distances from 5 to 25 m with one exception of 68 m.

These studies measured and explained the spatial variability of snow mechanical properties, but did not explain the effect of this variability on slope stability. Kronholm and Schweizer (Reference Kronholm and Schweizer2003) proposed a conceptual model to explain the effect of the spatial variation of the stability on the overall slope stability. Short-range variation could have a stabilizing effect on the snowpack and the long-range variation could have a so-called ‘knock-down effect’ on the slope stability, but further investigation through mechanical models was needed to test this conceptual model. Several studies simulated artificial spatial patterns of the weak layer into mechanical models to explain the effect of the spatial variability of the weak layer on the overall slope stability (Fyffe and Zaiser, Reference Fyffe and Zaiser2004; Kronholm and others, Reference Kronholm, Schweizer, Schneebeli and Pielmeier2004; Schweizer and others, Reference Schweizer, Kronholm, Jamieson and Birkeland2008; Gaume and others, Reference Gaume, Chambon, Eckert and Naaim2013, Reference Gaume2014). First, some studies used cellular automata models and showed the effect of the variance shear strength on the slope stability (Fyffe and Zaiser, Reference Fyffe and Zaiser2004; Faillettaz and others, Reference Faillettaz, Louchet and Grasso2004; Kronholm and Birkeland, Reference Kronholm and Birkeland2005). High shear strength variances create more deficit zones and cause easier overall failure of the slope even with strong zones. However, these models only account for the state of the neighbor cells and large-scale elastic redistribution could not be taken into account, therefore the link with the correlation length could not be explored. Finite-element method (FEM) can handle large-scale elastic redistribution and was used in several studies to explain the influence of the correlation length over the slope stability. Gaume and others (Reference Gaume, Chambon, Eckert and Naaim2013) explored how the stress redistribution induced by the elasticity of the slab could smooth the heterogeneity of the weak layer. They showed, in particular, that if the correlation length is smaller than the characteristic elastic length of the system, it behaves as in a homogeneous case. When the correlation length is larger than this elastic length, the smoothing does not take place and the system is more likely to fail even for large slab depth which illustrated the so-called knock-down effect (Gaume and others, Reference Gaume, Chambon, Eckert and Naaim2013, Reference Gaume2014). Gaume and others (Reference Gaume, Chambon, Eckert, Naaim and Schweizer2015) use the same method to estimate the propensity for tensile failure in the slab in order to relate to the avalanche release size. Weak layer heterogeneity increases slab tensile failure propensity for soft and shallow slabs, thus potentially smaller avalanches. On the other hard and deep slabs were hardly influenced by weak layer heterogeneity which led to wide-spread crack propagation.

These FEM studies focused exclusively on the spatial variation of the weak layer cohesion and its influence on natural avalanche release. It has been demonstrated numerous times, through survey and modeling, that snow depth is highly variable in mountainous areas (e.g. Winstral and others, Reference Winstral, Elder and Davis2002; Deems and others, Reference Deems, Fassnacht and Elder2006; Mott and others, Reference Mott, Schirmer and Lehning2011; Schirmer and others, Reference Schirmer, Wirz, Clifton and Lehning2011; Grünewald and others, Reference Grünewald2013; Hubbard and others, Reference Hubbard2018), especially in avalanche start zones (Miller and others, Reference Miller, Peitzsch, Sproles, Birkeland and Palomaki2022). The slab depth spatial variability should be related to the spatial variation of snow depth. Therefore, the spatial variation of the slab depth should affect the skier-triggering probability over an entire slope. For homogeneous cases, the influence of slab depth on skier-triggering was analyzed based on stress over strength approaches (Föhn, Reference Föhn1987; Habermann and others, Reference Habermann, Schweizer and Jamieson2008; Monti and others, Reference Monti, Gaume, Van Herwijnen and Schweizer2016) but also to address crack propagation propensity (Heierli and others, Reference Heierli, Gumbsch and Zaiser2008; Gaume and others, Reference Gaume, Van Herwijnen, Chambon, Wever and Schweizer2017). To the best of our knowledge, there is no study on the effect of slab depth spatial variation on the probability of skier-triggering and crack propagation. Slab depth variability should also affect the avalanche possible size. Slab properties, mainly slab depth and density, are one of the main drivers for dynamic crack propagation (McClung, Reference McClung1981; Heierli and others, Reference Heierli, Gumbsch and Zaiser2008; Gaume and others, Reference Gaume, Van Herwijnen, Chambon, Wever and Schweizer2017). The spatial variation of the slab-weak layer system should affect the stress in the slab and might promote crack arrest caused by slab tensile failure. There is a need for further investigation on that matter in order to provide estimates of the avalanche release size which is crucial information for avalanche forecasting and risk management.

Several tools have been used to understand dynamic crack propagation. Previous studies on the influence of spatial variability of snow on the release and the avalanche size used mainly mesh-based approaches which can handle large deformations and fracture propagation at the (significant) cost of re-meshing and mesh refinement techniques. Some researchers used the discrete element method to model snow but are limited to small computational domains from the microstructure scale (Hagenmuller and others, Reference Hagenmuller, Chambon and Naaim2015; Mede and others, Reference Mede, Chambon, Nicot and Hagenmuller2020) to a few meters scale (Gaume and others, Reference Gaume, Van Herwijnen, Chambon, Wever and Schweizer2017; Bobillier and others, Reference Bobillier2021). More recently, the material point method (MPM), a hybrid Eulerian–Lagrangian technique showed promise in simulating solid–fluid transitions and crack propagation in geomaterials (Sulsky and others, Reference Sulsky, Chen and Schreyer1994). Gaume and others (Reference Gaume, van Herwijnen, Gast, Teran and Jiang2019) propose an elastoplastic MPM with a new snow constitutive model to simulate the mechanical behavior of snow slabs and weak snow layers. With this model, they can simulate in a unified way, numerous important mechanical processes in a snow slab avalanche, from the weak layer failure initiation, dynamic crack propagation, slab tensile fracture, and, finally the release and the flow of the slab down the slope. Trottet and others (Reference Trottet2022) used this method and full-scale measurements to reveal a transition between anticrack propagation (closing crack/mode – I) and so-called ‘supershear’ propagation in which the fracture occurs in shear (mode II) at a speed larger than the shear wave speed (of the slab). They report that this transition requires a slope angle larger than the snow friction angle (≈ $27^\circ$) and a propagation distance larger than typically 3–5 m. This suggests that a pure shear interface model could be sufficient to simulate large avalanche releases on an inclined slope. This finding, together with the large computational cost of 3D MPM simulations motivated us to use the depth-averaged MPM (DAMPM) recently proposed and validated by Guillet and others (Reference Guillet, Blatny, Trottet and Gaume2023). DAMPM enables a fast computation time over large domains, allowing us to produce a vast number of simulations to better understand the effect of the slab depth variation on the avalanche release size.

Understanding how the spatial variation of slab depth influences the probability of skier-triggering and the avalanche release size is of great importance. This could lead to an improvement in snow avalanche forecasting and decision-making in avalanche terrain for backcountry recreationists. To better understand this issue, we propose a combined mechanical–statistical approach to study how spatial variation of slab depth affects the skier-triggering probability and possible avalanche release size. First, a sensitivity analysis is made for the skier-triggering probability in relation to the spatial variation of the slab depth. Secondly, we use our approach to test the effect of skiing style and downhill strategy on skier-triggering probability. Lastly, DAMPM simulations allowed us to investigate the relation between slab depth variations and the avalanche release size, by analyzing the propagation distance leading to the first tensile fracture in the slab.

Methods

Spatial variability of slab depth

Gaussian random fields (GRF) will be used to generate artificial 2D surfaces as input into our numerical mechanical models. Each point of the surface in space (x,  y) can be defined as a random variable, so the collection of random variables is called a random field defined by:

(1)$$D( x,\; y) \in \overline{D} \cdot C$$

where D(x,  y) is the slab depth random field, $\overline {D}$ is the mean slab depth and C is the Gaussian covariance model defined by the formulation in gstools v1.3 documentation (Müller and others, Reference Müller, Schüler, Zech and Heße2022):

(2)$$C( d) = S^2_D \left[1- \exp \left({d\over \epsilon}\right)^2 \right]$$

where d is the distance between the observations, $S^2_D$ is the slab depth variance and $\epsilon$ is the correlation length of the slab depth variation. We used a Gaussian covariance model without a nugget. For each GRF, we can specify the mean and the covariance function, the last one is defined by a variance and a correlation length. A sensitivity analysis is presented on these three parameters of the slab depth spatial variation for both the skier-triggering probability and avalanche release size. We test the mean slab depth from 0.5 m to 1 m with a 0.1 m increment. Several studies have shown that snow mechanical properties can be approximated by a Spherical and Gaussian covariance function with correlation lengths ranging mostly from 5 to 20 m (Kronholm and Schweizer, Reference Kronholm and Schweizer2003; Landry and others, Reference Landry2004; Feick and others, Reference Feick, Kronholm and Schweizer2007; Lutz and others, Reference Lutz, Birkeland, Kronholm, Hansen and Aspinall2007; Bellaire and Schweizer, Reference Bellaire and Schweizer2011; Lutz and Birkeland, Reference Lutz and Birkeland2011; Reuter and others, Reference Reuter, Richter and Schweizer2016) and sometimes 50 m (Reuter and others, Reference Reuter, Richter and Schweizer2016). Based on these studies, we chose to test correlation length from 5 m to 40 m with an increment of 5 m. The idea is to tend toward a very smooth random field close to a homogeneous case. We took the same approach with the variance, from 0 to 0.025 m2 which represents approximately 0.3 m from the mean slab depth to maximum and minimum values. The selected variance values were based on field measurements done by Meloche and others (Reference Meloche, Gauthier and Langlois2023). Gaussian random fields were generated using the gstools v1.3 package in Python (Müller and others, Reference Müller, Schüler, Zech and Heße2022).

Skier-triggering probability

One of the specific objectives of this study is to evaluate the skier-triggering probability as a function of slab depth variations. The snow properties were selected to represent a meta-stable slab and weak-layer system where the natural release is not possible but only the skier-triggering. Different snow mechanical properties can be related to each other (Jamieson and Johnston, Reference Jamieson and Johnston1990; Scapozza and others, Reference Scapozza, Bucher, Amann, Ammann and Bartelt2004; Sigrist, Reference Sigrist2006). In general, it has been demonstrated that the increase in slab depth will also increase the snow density, elastic modulus, and shear strength of the weak layer. We computed realistic snow mechanical values based on empirical power-law functions obtained based on literature data. First, the snow density ρ is related to the mean slab depth $\bar D$ according to Eqn (6) in McClung (Reference McClung2009):

(3)$$\rho = 100 + 135 \bar D^{0.4}$$

Then, we computed the elastic modulus E based on the snow density ρ according to Sigrist (Reference Sigrist2006):

(4)$$E = 9.68 \times 10^8 \left({\rho\over \rho_{ice}}\right)^{2.94}$$

where ρ ice = 917 kg m−3. Note that, contrary to the slab depth, the density and elastic modulus of the slab does not spatially vary in our simulations but are related to the mean slab depth. Finally, the shear strength of the weak layer τ p was computed according to the following power–law relationship from Bažant and others (Reference Bažant, Zi and McClung2003) adapted by Gaume and others (Reference Gaume2014):

(5)$$\tau_p = c + 1370D^{1.3}$$

where c is the cohesion set to 300 Pa. This allows us to account for the local friction effect where the slab depth is locally increasing.

Stability metrics

We choose to assess the skier stability based on the skier propagation index (SPI) proposed by Gaume and Reuter (Reference Gaume and Reuter2017). The index consists of the ratio between two lengths, namely the critical crack length a c and the skier crack length l sk (Gaume and Reuter, Reference Gaume and Reuter2017). The skier crack length is computed by solving the equation: τ + Δτ = τ p, where $\tau = \rho g D \sin \psi$ is the shear stress due to the slab weight on an inclined slope ψ and g is the gravitational acceleration constant. The additional stress due to the skier standing on the snow is defined by (Föhn, Reference Föhn1987; Monti and others, Reference Monti, Gaume, Van Herwijnen and Schweizer2016):

(6)$$\Delta \tau = {2 R \cos \alpha \sin^2 \alpha \sin( \alpha + \psi) \over \pi D}$$

where R is the skier load set to 780 N and ψ is the slope angle set to $35^\circ$. We find the two roots of the equation given two angles α 1 and α 2, where total shear stress is equal to the shear strength of the weak layer. We used the two angles α 1 and α 2 to find the skier crack l sk with the following equation:

(7)$$l_{sk} = D \left[{1\over \tan \alpha_1} - {1\over \tan \alpha_2}\right]$$

The critical length a c is computed using the formulation from Gaume and others (Reference Gaume, Van Herwijnen, Chambon, Wever and Schweizer2017):

(8)$$a_c = \Lambda \left[{- \tau + \sqrt{ \tau^2 + 2\sigma ( \tau_p - \tau) }\over \sigma}\right]$$

where $\sigma = \rho g D \cos \psi$ and Λ is a characteristic length of the system defined by:

(9)$$\Lambda = \sqrt{{E^{'}D D_{wl}\over G_{wl}}}$$

with E  = E/(1 − ν 2). The weak layer thickness D wl and the shear modulus G wl were set to 0.04 m and 0.2 MPa respectively, ν is the Poisson ratio set to 0.3. The skier propagation index SPI is thus defined as:

(10)$$SPI = {a_c\over l_{sk}}$$

These formulas allow us to generate SPI maps from our corresponding GRF slab depth and snow properties maps over a 200 m by 100 m fictional slope (Fig. 1). For each GRF realization, we simulated sinusoidal ski tracks all over the fictional slope representing a ‘modern freeride’ skiing trajectory defined by a down-slope turn radius of 10 m and cross-slope amplitude of 5 m (Fig. 1). The spacing between the skier was held constant at 5 m with a total of 40 skiers. We recorded a hit if a skier track passed through a zone with SPI below 1. We computed the probability of skier-triggering with the number of skier tracks who recorded a hit compared to all skier tracks on the slope. A convergence of analysis for the total number of skiers on the slope is presented in the appendix (Fig. 11).

Figure 1. Example of one realization of a Gaussian Random Field GRF for slab depth D, slab density ρ, skier crack length l sk, critical crack length a c, skier propagation index SPI and skier tracks with SPI. The slope is reduced to 50 m by 100 m only for visualization purposes.

A secondary objective of this study was to assess the influence of skiing style or skiing trajectory on the skier-triggering probability. Different trajectories were tested on the basis of two ‘extreme’ trajectories. The first one is to mimic a pure linear trajectory which is defined by the projected weak spot length on the x-axis (cross-slope) compared to the total cross-slope length. This ratio was obtained following these two steps: (1) the presence of weak spots in the up-slope direction is checked for every point following a transect in the cross-slope direction, and (2) a length is obtained with the sum of every presence of weak spot along this transect and then compared to the cross-slope length. The second extreme trajectory mimics a skier who will span the entire slope in a cross-slope direction which would yield a skier-triggering probability of one.

Possible avalanche size

To link the spatial variability of slab depth to the avalanche release size, a method is needed to compute the dynamic crack propagation in a weak snow layer. The finding from Trottet and others (Reference Trottet2022) supports the physical assumptions needed for a depth-averaged method that integrates the momentum and mass conservation equation in the z direction. Guillet and others (Reference Guillet, Blatny, Trottet and Gaume2023) presents a detailed view of this method and the integration of the governing equation. We will present the key assumptions but please refer to Guillet and others (Reference Guillet, Blatny, Trottet and Gaume2023) for an in-depth view of the method. The first key assumption is the classic shallow water assumption where the vertical length is shorter than the horizontal length, which translates in an avalanche context as ${h_0\over L} \ll 1$ where h 0 is the standard height of the slab and L the characteristic length of the avalanche. The material is assumed incompressible meaning that the density ρ does not depend on position either time and place, and the flow surface is stress-free at the top of the slab where σ|h=z = 0. Note here, that the method could be easily adapted in compressible form if the ρ needs to be as a function of the particle height and the position. The velocities in the x direction are similar to the ones in the y direction but the velocities in the z direction are small and negligible. The other particularity of the depth-averaged method is the column-shaped particle of height h = D where the integration point of σ zz is h/2 (Fig. 2), which gives us this depth-averaged equation of mass conservation:

(11)$${\partial h\over \partial t} + {\partial ( h \overline{v}_x) \over \partial x} + {\partial( h\overline{v}_y) \over \partial y} = 0$$

where $\overline {v}_x$ and $\overline {v}_y$ are the depth-averaged velocity field at the integration point of the particle. The last assumption is a plane stress assumption with σ zy = σ zx = 0. Basal forces are applied at the interface between the slab and the weak layer defined by:

(12)$$\tau_{xz}\, \colon = \sigma_{xz}\vert _{z = 0},\; \tau_{yz}\, \colon = \sigma_{yz}\vert _{z = 0}$$

which give also σ zz|z=0 = ρgh at the bottom of the slab column and $\overline {\sigma }_{zz} = {1\over 2}h\rho g$ at the integration point. This allows us to have the depth-averaged non-conservative form of momentum conservation:

(13)$$\rho h {\overline{d}\overline{v}_x\over \overline{d}t} = {\partial( h \overline{\sigma}_xx) \over \partial x} + {\partial( h \overline{\sigma}_xy) \over \partial y} - \tau_{xz} + g \rho h .$$
(14)$$\rho h {\overline{d}\overline{v}_y\over \overline{d}t} = {\partial( h \overline{\sigma}_yy) \over \partial y} + {\partial( h \overline{\sigma}_xy) \over \partial x} - \tau_{yz} + g \rho h .$$

Figure 2. DAMPM model and simulation parameters. (a) The geometry of the simulated propagation saw test PST with a sinusoidal slab depth variation and shear strength associated. The slab depth variation parameters from the sinus function are the mean slab depth $\overline {D}$, the standard deviation S D, and the correlation length $\epsilon$. (b) Slab elastoplasticity model following a Modified Cam-Clay yield surface. (c) Weak-layer model as quasi-brittle interface.

The slab is represented with an elastoplastic model following a Modified Cam-Clay yield surface γ in the p − q space (Gaume and others, Reference Gaume, Gast, Teran, van Herwijnen and Jiang2018):

(15)$$\gamma( p,\; q) = q^2( 1 + 2\beta) + M^2( p + \beta p_0) ( p-p_0) $$

where M is the cohesionless critical state line, β is the cohesion parameter that quantifies the ratio between the tensile and compressive resistance and p 0 is the consolidation pressure that affects the size of the yield surface. With M and β being constant respectively at 0.3 and 1.2, we related the slab tensile strength σ t to p 0:

(16)$$p_0 = -( 1-\beta) + \sqrt{\left({( \beta + 1) p\over 2\beta}\right)^2 + \left({q\over M}\right)^2 \left({( 1 + 2\beta\over \beta}\right)}$$

where $p = {\sigma _t\over \sqrt {3}}$ and $q = {\sigma _t\over 2}$ considering the plane stress hypothesis. The weak layer is an external force represented by a quasi-brittle interface with a softening behavior when the displacement u reaches the critical displacement u c defined by the shear stress reaches τ p (Fig. 2). Then we have the softening until the displacement reaches the residual displacement u r defined by the residual friction τ r with the snow friction angle Φ = 27°. The softening displacement is set to δ = 2u c, as suggested in Gaume and others (Reference Gaume, Chambon, Eckert and Naaim2013). The snow parameters are the same as in the skier method regarding snow density and elastic modulus, as they are set according to the mean slab depth values of the simulated slope via a power–law fit. The shear strength is set according to the local slab depth values to represent the friction for thicker slabs. The slope angle is also the same as the previous method set at $35^\circ$. We used the empirical power–law fit to link the slab tensile strength with the mean slab density according to Sigrist (Reference Sigrist2006):

(17)$$\sigma_t = 2.4 \times 10^5 \left({\rho\over \rho_{ice}}\right)^{2.44}$$

The depth-averaged material point method is more computer-intensive and time-consuming compared to the analytical method. A GRF simulation of the slab depth required at least 50 simulations per set of GRF parameters to obtain a statistical distribution and get representative results. We changed our approach and simulated a sinusoidal slab depth variation to reduce the number of simulations to one and have a deterministic view. The variance parameter is changed to standard deviation S D representing the amplitude of a sinus function (Fig. 2). We simulate very long propagation saw tests (PST) of 75 m in the up-slope direction and 0.30 m wide (Gauthier and Jamieson, Reference Gauthier and Jamieson2008). For each simulation, the cohesion is numerically removed from the bottom of the slope to obtain a critical crack length that will start the dynamic crack propagation across the slope. Finally, a tensile fracture is needed in the slab to be released from the slope and create a slab avalanche. This type of fracture in the slab occurs when the tensile stress in the down-slope direction (σ xx) reaches the tensile strength of the slab σ t. The distance to the first tensile fracture in the slab is noted for each simulation, we called this distance the tensile length L t.

Results

Sensitivity analysis of the skier-triggering probability

The probability of skier-triggering decreases with the increase of the mean slab depth as expected (Fig. 3). The homogeneous cases with zero variance show stable snowpack for skiers triggering from 0.6 m to 1 m slab depth. We observed two distinct regimes, one for a slab depth of 0.5 m where every skier is triggering for both homogeneous or heterogeneous cases. The second regime is defined with a 1 m mean slab depth where every skier doesn't trigger except for the larger variance at 0.025 m2. There is an intermediate regime for the other values of mean slab depth which is affected by both the variance and the correlation length. The probability of skier-triggering increases with the slab depth variance. The increase in the slab depth variance allows some areas of the fictional slope to have shallow slab depth and create weak zones where the SPI is below 1. The increase of the correlation length is decreasing the skier-triggering probability. This decrease is caused by the reduction of the number of weak spots with SPI below 1 across slopes. A small correlation length creates more weak spots where SPI is below 1 and a large correlation length creates fewer but bigger weak spots with SPI below 1. Instead of the mean presented above, we looked into the distribution of the skier-triggering probability containing 100 realizations. Figure 4 shows different probability density functions for each specific set of GRF parameters. With a mean probability below 0.3, the distribution is skewed towards 0 like a log-normal distribution. For cases where the mean skier-triggering probability range from 0.3 to 0.6, the distribution is relatively flat and centered, like a normal distribution. Even if the mean value is around 0.4 or 0.5, the variance of these distributions is quite large from 0.2 to 0.8 skier triggering probability. This means that for the same GRF parameters, some realizations were very unstable with more than half of the skiers triggered an avalanche and some realizations with very few skiers triggered. These cases in the intermediate regime described above from 0.6 to 0.9 m mean slab depth, the spatial variability of slab depth adds uncertainty to the probability to trigger an avalanche by a skier. With a mean probability above 0.8, the distribution is normally distributed around the mean values.

Figure 3. Sensitivity analysis for the mean skier-triggering probability with regards to the mean, spatial variance and correlation length of the slab depth. The mean probability is computed from a distribution of 100 realizations for each specific set of mean slab depth, variance and correlation length.

Figure 4. Probability density function of the skier-triggering probability for mid to low mean skier-triggering probability. All the distributions presented are from a GRF using a 0.7 m mean slab depth, 0.0025–0.0075 m2 slab depth variance, and 10-20-30 m correlation length.

Influence of the skiing style

The previous analysis was conducted using a constant skiing style defined by a 10 m down-slope turn radius (R down) with a 5 m cross-slope amplitude (A cross) (Fig. 1). However, these two parameters should influence the trajectory of each skier and therefore, should also affect the probability of the skier hitting a weak spot. We made a sensitivity analysis of these two parameters. We test multiple values to get a down-slope linear trajectory and the complete opposite with a trajectory that will traverse the entire slope in the cross-slope direction. These two extreme trajectories should mimic a freeride down-hill skiing trajectory (linear down-slope) compared to an up-hill skinning trajectory (cross-slope). Figure 5 shows that for a large A cross/R down ratio, the mean skier probability is increasing towards a probability of one with positive hits for every skier, meaning that a trajectory with a large cross-slope amplitude is more likely to encounter weak spot and trigger an avalanche. For a small A cross/R down ratio, the mean skier probability is decreasing towards a value determined by a ratio that we called the linear weak spot cross-slope ratio (${\sum {\hat {L}_x}}/{L_x}$). This ratio indicates the minimum probability of a purely linear trajectory specific to each realization per set of GRF parameters. Note that the 0.505 found in (Fig. 5) represents the mean of the linear weak spot cross-slope ratio for 100 realizations for a mean slab depth of 0.7 m, variance of 0.0075 m2, and 20 m correlation length.

Figure 5. Mean skier-triggering probability from 100 realizations for different skiing style ratios A cross/R down. A cross represents the cross-slope amplitude and R down represents the down-slope turn radius. A small skiing style ratio represents a linear down-slope trajectory and a large skiing style ratio represents a cross-slope trajectory. The probabilities are constrained by two values: the first is a probability of 1 where all skiers have triggered, and the second value is a linear weak spot cross-slope ratio between the sum of weak spot length in the cross-slope direction compared to the total cross-slope length. The dashed line is set at 0.505 which is the mean of the linear weak spot cross-slope ratio for 100 realizations for this set of GRF parameters: mean slab depth of 0.7 m, variance of 0.0075 m2, and 20 m correlation length. This line should move with regard to the GRF parameters. The inlets represent schematic skiing style based on the skiing style ratios.

Influence of group size and terrain choice

We investigated the influence of the group size on the skier-triggering probability. Here, we want to test the hypothesis that it is safer to ski near a preexisting ski track that is considered safe, compared to a completely random approach. We randomly selected a position at the top of the slope to start the first skier, and if the first skier track didn't record a hit on a weak spot, we keep adding a skier 5 m apart until a trigger was recorded or the slope was entirely skied. We repeated this operation 50 times on one realization and repeated it for 100 realizations for a 0.7 m mean slab depth and 0.005 m2 variance, with four different correlation lengths (5, 10, 20, 30 m). Figure 6 is showing that for a correlation of 5 and 10 m, the random and structured approaches have a similar experimental cumulative density function (ECDF) but the structured approach is slightly shifted. The ECDF for the 5 and 10 m correlation length had a median of one or two additional skiers which can be translated into a slightly lower skier-triggering probability compared to the 20 and 30 m ECDF. For the simulation with a correlation length of 20 and 30 m, the ECDF of the structured approach is completely shifted from the random approach, towards more additional skiers before triggering. The ECDF is starting at two additional skiers for the 20 m and the 30 m distribution, which means that a minimum of two additional skiers were needed before recording a trigger compared to the random approach, from all the 5000 simulations represented in one ECDF. The difference is more significant for the median of the ECDF, the random approach as between 3 to 4 additional skiers before the trigger compared to the structured approach with 7 skiers (20 m) and 10 skiers (30 m).

Figure 6. Experimental cumulative density functions (ECDF) of the number of additional skier to trigger from mid to low mean probability. All the distributions presented are from a GRF using a 0.7 m mean slab depth, 0.005 m2 slab depth variance, and 5-10-20-30 m correlation lengths. The inlets show examples of the corresponding SPI map specific to their GRF parameters.

Tensile length and avalanche release size

Figure 7 shows different simulations of PST for three different correlation lengths. During a dynamic crack propagation for a homogeneous case, the tensile stress σ xx increased linearly as the unsupported slab grew from the damaged weak layer. Then the tensile stress σ xx reached the tensile strength σ t, and a tensile fracture in the slab is observed. The increase is linear because the shear stress is constant across the slope in a homogeneous case, as the crack tip moves across the slope at 1.6 C s. However, the tensile stress pattern changed for different cases of slab depth variations. If the correlation length is large, around 25 m or more, the tensile length converges towards the homogeneous case because the tensile stress is increasing almost constantly. Figure 7a shows a simulation for a mean slab depth of 0.7 m, a standard deviation of 0.25 m, and a correlation length of 30 m where the tensile stress σ xx is constantly increasing in the lower part of the slope (distance up-slope < 20 m). Then, the tensile stress increases non-linearly to reach the tensile strength at ≈ 34 m. Tensile stress σ xx increases rapidly as shear strength τ p and shear stress τ xz reduces around 25 m. This smooth spatial variability with a long correlation length results in a tensile length similar to the homogeneous case. Figure 7b shows a simulation for a mean slab depth of 0.7 m, a standard deviation of 0.25 m, and a correlation length of 15 m where the tensile stress fluctuates as the crack tip moves across the slope. The same nonlinear increase is observed around 15 m up-slope in the tensile stress, but then it decreases as the slab depth, the shear stress, and strength increase again around 25 m up-slope (Fig. 7b). Finally, the tensile stress increases a second time as the slab depth, shear stress and strength start to decrease around 40 m up-slope (Fig. 7b). In this particular case, the spatial variability of the slab depth and the underlying weak layer strength cause a fluctuation in the tensile stress of the slab σ xx, resulting in a longer tensile length. Figure 7c shows the same fluctuation in tensile stress but for a 10 m correlation length. The fluctuation in tensile stress is more significant and closer to the bottom of the PST, leading to a shorter tensile length. From a static point of view, tensile stress builds as the length of the ‘unsupported’ slab increases due to weak layer damage and crack propagation. The tensile stress is equal to the load from the slab in the down-slope minus the friction of the slab weight. This relation is linear assuming a constant slab depth. However, our system had a variation in slab depth that will also cause a variation in the friction effect that is more pronounced where the slab is locally thicker and explains why the tensile stress locally reduces where the slab is thicker (Fig. 7). Dynamic effects could also explain some fluctuations in the tensile stress. In fact, variations in shear stress and weak layer strength lead to variations in crack speed around 1.6 C s, which can also cause fluctuations in tensile stress.

Figure 7. Three different regimes of tensile fracture for a 0.7 m slab depth $\overline {D}$ and 0.25 m S D. These three simulations show the last frame saved just before the tensile fracture occurs when σ xx = σ t. The shear stress τ xz and the weak layer shear strength τ p and the cohesion c are also represented. The crack tip (dotted line) is located just behind the peak of τ xz at the loss of cohesion c. The distance between the crack tip and the τ xz peak is due to the softening δ. The bottom plot shows the corresponding crack speed $\dot {a}$ which is normalized over the shear wave speed $C_s = \sqrt {{G}/{\rho }}$, and the slab depth D in m. (a) PST simulation with a $\epsilon$ 30 m just before a tensile fracture occurs. (b) PST simulation with a $\epsilon$ of 15 m just before a tensile fracture occurs. (c) PST simulation with a $\epsilon$ of 10 m just before a tensile fracture occurs.

We present a sensitivity analysis of the propagation distance that results in the first tensile fracture (L t) from our numerical PST experiment. Figure 8 shows all the results from our simulations with different mean slab depth values $\overline {D}$, slab depth standard deviation S D (sinus function) and correlation length $\epsilon$. The homogeneous tensile length is obtained here based on a simulation with homogeneous slab depth (i.e. standard deviation of zero). This homogeneous tensile length increased with the slab depth even if the theoretical quasistatic tensile length is in principle not linked to the slab depth ($L_t = {\sigma _t\over \rho g \sin \psi }$). However, in our study, the slab density and tensile strength are related to the mean slab depth Eqns (3) and (4), which explains the reported increase in the tensile length obtained for our homogeneous cases (Fig. 8). A shorter tensile length is obtained as the standard deviation increases. A longer tensile length is obtained as the correlation length increases around 25 m, then, it converges towards the same values as the homogeneous case. We observed a tensile length approximately 20 m shorter than the homogeneous case when the standard deviation is 0.2 m and a correlation length of 10 m or less. The tensile length is only longer than the homogeneous case for a correlation length of 15 m and 20 m for higher slab depth, but also for a standard deviation of approximately 0.1 m and higher (Fig. 8). This regime with larger tensile lengths is more pronounced for thicker slab depth. This particular regime with longer tensile lengths, which is associated with a correlation length of 15 or 20 m, is caused by the use of the sinus function. This function caused an increase in the weak layer strength around 30–40 m, which reduced the tensile stress in the slab just before it would have reached the tensile strength σ t, thus resulting in a longer tensile length (Fig. 7b). The correlation length has a major influence on the strength of the weak layer, τ p, with a shorter correlation length causing the peak to move closer to the bottom of the slope, resulting in a shorter tensile length than in the homogeneous case. However, cases with a longer correlation length (>25 m) have a similar behavior as cases with homogenous properties (Fig. 7a). The sharp transition in tensile length around 15–20 m of correlation length in our result (Fig. 8) is due to the sinus function itself, and this could be smoothed out by performing numerous simulations with sinus functions of different phases (i.e. by shifting the origin of function) or by using a GRF-based simulation (Appendix Fig. 12).

Figure 8. Sensitivity analysis for the tensile length L t with regards to the mean $\overline {D}$, standard deviation S D and correlation length $\epsilon$ of the slab depth sinus function.

To further investigate the results presented above in the case of a sinus function, we used GRF to simulate slab depth variation for a few GRF parameters. Figure 9 shows the distribution of tensile lengths from 50 realizations for four different sets of GRF parameters. The dashed line represents the homogeneous tensile length. For the small variance $S^2_D$ (0.005 m2), the distribution is narrow and centered around the homogeneous tensile length. For the higher $S^2_D$ (0.025 m2), the distribution of tensile length has a large variance, especially for the 5 m correlation length with values of tensile lengths ranging from 10 to 50 m. The distribution for a 1 m slab depth has nearly the same distribution shape, which is narrow for a small value of 0.005 m2 $S^2_D$ and wider for a $S^2_D$ of 0.025 m2 (Fig. 9). The variance of tensile length distribution is smaller for a 1 m mean slab depth compared to the 0.5 m distributions. The medians of tensile length distributions for the 1 m mean slab depth are larger compared to the homogeneous values denoted by the dashed line in (Fig. 9). The distributions are shifted towards bigger tensile length values compared to the homogeneous tensile length, with either a small or high variance (Fig. 9). This could be explained by a larger friction effect by the 1 m mean slab depth, causing a less important build-up of tensile stress in the slab which resulted in tensile length values larger compared to the homogeneous tensile length.

Figure 9. Probability density functions of tensile lengths L t of 50 realizations for different mean slab depths $\overline {D}$ of 0.5–1 m, different variances $S^2_D$ of 0.005–0.025 m2, and 5–15–30 m correlation lengths $\epsilon$. The dashed line represents the homogeneous tensile length for a mean slab depth of 0.5 m and 1 m.

Skier-triggering probabilities versus potential avalanche release sizes

This last result section presents both the sensitivity analysis of the skier-triggering probability and the potential avalanche release size. To obtain the potential size of the avalanche release, we multiplied the tensile lengths by the mean slab depth to get an estimate of the volume of snow mobilized for the avalanche. Typically the avalanche release size is computed from the volume of snow in movement but our simulations setup does not include the cross-slope length of the potential avalanche. Figure 10 shows both the probability of skier-triggering and the potential avalanche release size. The skier-triggering probability appears to be inversely related to the mean slab depth because the force induced by a skier at a given depth is inversely proportional to the depth. On the contrary, the potential avalanche release size increased with slab depth. We obviously got a correlation as we multiplied the tensile length by the mean slab depth to get the potential avalanche release size. However, the tensile strength in our simulations was parametrized based on the mean slab depth which also explains the longer tensile length values for thicker and stronger slabs. Furthermore, (Fig. 10) shows that the skier-triggering probability is increasing, with increasing the standard deviation for a given mean slab depth. However, the avalanche release size should be smaller when the standard deviation is increasing, but this result should be nuanced because (Fig. 9) shows that with a more natural spatial variability generated from a GRF, the avalanche size is quite variable compared to the homogeneous case but tends to be larger while the mean slab depth is increasing. The area in the heatmap where the maximum probability is correlated with the area of minimum potential avalanche release size, and the opposite is also present with the minimum of probability with the maximum size (Fig. 10). For the same mean slab depth values, high variation leads to a high skier-triggering probability but a lower potential avalanche release size. As the mean slab depth increases, the skier-triggering probability decreases to a point that for 0.9 and 1 m mean slab depth, the probability to trigger by a skier is almost impossible except with high slab depth variation, but the trigger could lead to relatively larger avalanches. These cases represent a scenario of low probability but high consequences with large avalanches, and this scenario is only possible with a slab depth spatial variation.

Figure 10. Probability of skier-triggering and normalized potential avalanche release size in relation to the mean slab depth and standard deviation of the slab depth. Potential avalanche release size combines the tensile length normalized with the largest tensile length multiplied by the mean slab depth. We show the standard deviation slab depth values for visual purposes but the variance values used with GRF method yield approximately the same values as the standard deviation slab depth used with the sinus function.

Discussion

Relevance of the study for practical implications

This study presents a novel mechanical–statistical approach to understanding the influence of slab depth spatial variability on the skier triggering probability of potential avalanche size. First, we showed a sensitivity analysis of the three parameters defining the variability. The increase of skier-triggering probability is inversely proportional to the mean slab depth, which was expected considering previous studies on this matter but without slab depth variation (Föhn, Reference Föhn1987; Monti and others, Reference Monti, Gaume, Van Herwijnen and Schweizer2016; Gaume and Reuter, Reference Gaume and Reuter2017). However, we show that the tensile length and the potential avalanche size are increasing proportionally to the mean slab depth, which is in agreement with previous studies showing that thicker and stronger slabs promote larger avalanches (Gaume and others, Reference Gaume, Chambon, Eckert, Naaim and Schweizer2015). The variance and the correlation length results from the sensitivity analysis could be interpreted together. The combination of both creates some propagation spots (SPI below 1) on the fictional slope that skiers triggered. As the variance increases, it creates more propagation spots on the slope because it creates more areas where the slab is thinner so the skier can trigger the weak layer. A smaller correlation length leads to several small weak spots distributed across the slope compared to cases with longer correlation lengths, which led to fewer weak spots that cover more surface on the slope. The higher number of weak spots created using a smaller correlation length induced a higher skier-triggering probability than in the case with fewer weak spots covering more surfaces. In brief, a short-range variation creates numerous propagation spots leading to an increase in the skier triggering probability. Interestingly, several studies investigated the effect of the weak spots, created by heterogeneity in the weak layer, on natural release and obtained opposite conclusions (Gaume and others, Reference Gaume, Chambon, Eckert and Naaim2013, Reference Gaume2014). The short-range variation of the weak layer creates several weak spots that are distributed across the slope like the short-range variation of slab depth. These short-range variations can be smoothed due to the elasticity of the slab (Gaume and others, Reference Gaume, Chambon, Eckert and Naaim2013) and reduce the probability of a natural avalanche occurring. These studies also found that long-range variations create fewer weak spots but these weak spots were larger and covered more surfaces. This long-range variation was destabilizing the entire slope, in line with the so-called knock-down effect (Kronholm and Schweizer, Reference Kronholm and Schweizer2003; Fyffe and Zaiser, Reference Fyffe and Zaiser2004; Gaume and others, Reference Gaume2014). Finally, the variation of the snow mechanical properties (slab depth or weak layer cohesion), creates a spatial distribution of weak spots on the slope, and this variation does not have the same effect regarding the type of trigger between a skier (more unstable with a short-range variation) compared to a natural release (which is more unstable with a long-range variation).

This study also had an implicit objective to apply the method to test common knowledge that practitioners of the avalanche industry developed through many years of experience in the field. We realized that our method was heavily dependent on the skier style of the simulated skier trajectory. We show that a linear trajectory with a high down-slope radius R down and a small cross-slope amplitude A cross, reduce significantly the odds of triggering a weak spot. These results should be applied carefully in practice because it doesn't imply that skiing straight down the slope is ‘safer,’ whatever the term safer implicated in this context, but it only reduces the probability of triggering a weak spot resulting in an avalanche. The opposite trajectory was also simulated with a very high cross-slope amplitude and a small down-slope radius, representing an up-slope trajectory which we can translate to skinning up the up-slope with conversion (Fig. 5). Backcountry recreationists should not base their decision to ski a particular slope on their skiing trajectory. Decision-making in avalanche terrain is a complex task with many different aspects like terrain features, safety management, and other mountain hazards (Harvey and others, Reference Harvey, Rhyner and Schweizer2023)

We wanted to test if it was safer to ski closer to a preexisting ski track. Figure 6 shows a comparison between a structured approach that mimics skiing closely to a preexisting ski track from a completely random approach. The ECDF with a long correlation length had a median from 7 to 10 skiers on the slope before recording a trigger. It is important here to notice that in this method, the ECDF only represents cases where the first skier did not trigger, and then we started to add additional skiers both in a structured and random approach. The use of a safe first skier track is important because it mimics the fact that preexisting ski tracks could give information to other skiers that this trajectory did not trigger. Then, in spatial variation with a long correlation length like 30 m, the distance to the next weak spot could be on average 30 m away, explaining the fact that many skiers, with a spacing of 5 m could be on the slope before recording a trigger. These results confirm and quantify common knowledge used by ski guides and in avalanche awareness communication (Harvey and others, Reference Harvey, Rhyner and Schweizer2023).

Our results showed that the slab depth spatial variability adds randomness and unpredictability to skiing an avalanche-prone slope. A spatially homogeneous slab creates a binary outcome: either each skier triggers the avalanche or none do. But, the spatial variability of the slab depth creates a third regime in which some skiers trigger the avalanche and some do not on the same slope. The slab depth spatial variability creates weak spots on the slope which the skier trajectory will determine the outcome. The randomness is a result of the arbitrary anisotropic trajectory (down-slope) of the skier toward a potential weak spot on the slope. Our results also showed randomness in the tensile length obtained from our GRF simulations. The variation of slab depth sometimes induced an early crack arrest resulting in shorter tensile length, and sometimes the opposite outcome. The slab depth variation influences the crack speed during crack propagation. The observed increase in the speed of the crack caused a decrease in the tensile stress building up on the slab, which led to a longer tensile length. The same phenomenon was observed when the slab depth variation was slowing down the crack propagation, causing a sharp increase in tensile stress.

The last result presented in this study is the comparison between the skier triggering probability and the potential avalanche size. We show that it is more probable to trigger thinner and softer slabs compared to thicker and stronger slabs, but these thicker and stronger slabs could potentially create larger avalanche release sizes, also described and modeled by Gaume and others (Reference Gaume, Chambon, Eckert, Naaim and Schweizer2015). The increase of the slab depth standard deviation has an ambiguous effect because it increases the skier-triggering probability but reduces the avalanche release size. This latter was also observed by Gaume and others (Reference Gaume, Chambon, Eckert, Naaim and Schweizer2015) but regarding the variation of the weak layer cohesion instead of the slab depth on the avalanche release size. The relation between the likelihood to trigger by a skier compared to the propensity of propagation was initially described, through stability tests and field observations by van Herwijnen and Jamieson (Reference van Herwijnen and Jamieson2007). However, this study focused on fracture initiation and the propensity of propagation but not the potential avalanche size which refers to the dynamic crack propagation. Our statistical-mechanical provides a physically based validation and includes the effect of spatial variability of this well-known relationship (Fig. 10) which is the basis to describe the avalanche hazard in several countries (Statham and others, Reference Statham2018; Techel and others, Reference Techel, Karsten and Schweizer2020).

Limits of the study and outlooks for future work

The novel methods used in this study present some limitations and assumptions that could be explored in future work. The analytical method considered the skier loading static along the skier tracks. In reality, the skier adds more pressure to the snow cover at the apex of each turn. This additional pressure in the apex could potentially trigger the weak layer in thicker slabs. Also, skier penetration was not taken into account, and this could potentially affect some of the presented results. The additional pressure coupled with the skier penetration depth could increase the skier-triggering probability using a skiing style with more turns compared to a linear skiing style. In addition, in the DAMPM model, the volumetric collapse of the weak layer and the induced slab bending is not taken into account because of the depth-averaged assumptions. In principle, at such a scale on an inclined slope, the slab tension represented by the DAMPM model is significantly higher than the slab bending which is anyway limited by the slab touchdown slab behind the crack tip (Benedetti and others, Reference Benedetti, Gaume and Fischer2019).

We made the assumption that the weak layer strength would follow the slab depth variation locally. However, Bellaire and Schweizer (Reference Bellaire and Schweizer2011) has shown that is not always the case and the weak layer and the slab spatial pattern could differ. The relation between the slab depth and the weak layer strength is mainly due to the settlement and the friction from the slab weight, but some variation could still remain. The weak layer could be parameterized using the Mohr–Coulomb relation proposed by Gaume and others (Reference Gaume, Chambon, Eckert and Naaim2013), but with the friction term locally adjusted to the slab depth and the cohesion term could be set using a GRF with a different spatial pattern than the slab depth. This could lead to more realistic variations of snow properties and ultimately more realistic simulations. We choose not to follow this approach because we want to isolate only the slab depth variation to better understand individual drivers of the instability. Either approach should create weak spots triggered by skiers in the fictional slope, but maybe not in the same areas of the slope. However, the use of two different spatial patterns for the weak layer and the slab could create areas where the weak layer is stronger and the slab depth is thinner, the opposite of what this work is presenting. Such areas could promote slab tensile failure and potentially a crack arrest in the weak layer. Further investigations should be made on this matter to see if it could reduce the crack speed and potentially promote the crack to arrest, which we did not observe in our simulations. The covariance model used in the GRF did not contain any nugget. This choice created a smoother spatial realization of the slab depth without any ‘noise’ from the nugget. However, Kronholm and Birkeland (Reference Kronholm and Birkeland2005) has shown that increasing the nugget effect could promote crack arrest during dynamic crack propagation. This effect should be explored in future work regarding crack arrest and potential avalanche release size.

This study only investigates in numerical simulation the length at which the first tensile fracture occurred in the slab as a proxy to the potential avalanche release size. Tensile fracture is often related to crack arrest in the weak layer but not necessarily. There are no current studies to the best of our knowledge that explore the conditions of the crack arrest on an inclined snow slope. However, real-scale experiments on flat-terrain show some mechanical conditions when crack arrests were observed on 10 m long flat PST's (Bergfeld and others, Reference Bergfeld2021). They demonstrate some dissipation of energy during the dynamic crack propagation which could reduce the crack speed and possibly induce a crack arrest without a slab fracture. The dissipation of energy was due to the compression of the weak layer by the slab behind the crack tip. However, this phenomenon could be less important or may be absent on an inclined slope where the crack propagation changes to pure shear crack propagation (Trottet and others, Reference Trottet2022). Other dissipation mechanisms could influence the crack arrest like the softening behavior of the weak layer. Further investigation should focus on the effect of the softening on energy dissipation and crack arrest. Strong heterogeneity in the weak layer and topography changes should also be explored to further explain the conditions for a crack to arrest, and ultimately estimate the potential avalanche release size.

Conclusion

This study demonstrates the influence of slab depth spatial variability on the skier-triggering probability and the possible avalanche release area using a novel mechanical-statistical approach. We show that the spatial variability slab depth could increase the skier-triggering probability for thicker slabs when in a homogeneous case, a trigger by a skier is unlikely. For the possible avalanche release size, we show that the spatial variability of slab depth can induce a fluctuation in the tensile stress causing an early tensile failure resulting in smaller avalanches and also the opposite with bigger avalanches depending on the scale of the variability. We used the tensile length as a potential proxy for crack arrest but further research should focus on drivers for crack arrest dynamic crack propagation.

This study provides quantification and scientific evidence on the common knowledge that practitioners have developed throughout years of experience in the avalanche industry. We demonstrate the effect of skiing style on the probability to trigger an avalanche. We validate the idea with scientific evidence that skiing near a preexisting skier track could reduce your probability to trigger an avalanche compared to a random approach. This study demonstrates some processes during dynamic crack propagation regarding the variation of slab depth along a 1D slope. However, more research is needed to understand which drivers like topography or strong snow heterogeneity could potentially stop this dynamic crack propagation, both for the anticrack propagation in flat terrain and the super-shear regime on an inclined slope. Finally, this study shows, validates, and quantifies the well-known relationship between the likelihood and the size of an avalanche as well as common knowledge for safety guidelines in the avalanche community.

Acknowledgements

We want to thank all the SLAB members at EPFL, including Lars Blatny, Bertill Trottet, Hugo Rousseau, Thomas Pauze, Roxanne Fayant and Grégoire Bobillier who participated in the discussion and shared enthusiasm regarding this study during team meetings and coffee breaks. We also want to thank Stephan Harvey for his useful comments regarding the practical implications of this study. We thank Karl Birkeland and an anonymous reviewer for their helpful and constructive comments.

Appendix

The number of skiers on the slope to compute the skier-triggering probability is important to get a stable result. The convergence over the total number of skiers was checked and presented in (Fig. 11).

Figure 11. Convergence of the total number of skiers used to compute the probability of skier-triggering for GRF parameters of 0.7  m mean slab depth, 0.0075 m2 variance and 20 m correlation length. The blue line shows the convergence of the mean after 100 realizations and the orange line shows the standard deviation after 100 realizations.

The use of GRF for the PST simulations resulted in different values of tensile length for the same GRF parameters. The use of GRF also smooths the variation and, therefore, the fluctuation in tensile stress in the slab. Figure

Figure 12. Two different regimes of tensile fracture for a 0.7 m slab depth $\overline {D}$ and 0.025 m variance $S^2_D$. These three simulations show the last frame saved just before the tensile fracture occurs when σ xx = σ t. The shear stress τ xz and the weak layer shear strength τ p and the cohesion c are also represented. The crack tip (dotted line) is located just behind the peak of τ xz at the loss of cohesion c. The distance between the crack tip and the τ xz peak is due to the softening δ. The bottom plot shows the corresponding crack speed $\dot {a}$ which is normalized over the shear wave speed $C_s = \sqrt {G/\rho }$, and the slab depth D in m. (a) PST simulation with a $\epsilon$ of 30 m just before a tensile fracture occurs. (b) PST simulation using GRF with a $\epsilon$ of 5 m just before a tensile fracture occurs.

References

Bažant, ZP, Zi, G and McClung, D (2003) Size effect law and fracture mechanics of the triggering of dry snow slab avalanches. Journal of Geophysical Research: Solid Earth 108(B2), 111. doi: 10.1029/2002jb001884CrossRefGoogle Scholar
Bellaire, S and Schweizer, J (2011) Measuring spatial variations of weak layer and slab properties with regard to snow slope stability. Cold Regions Science and Technology 65(2), 234241. doi: 10.1016/J.COLDREGIONS.2010.08.013CrossRefGoogle Scholar
Benedetti, L, Gaume, J and Fischer, JT (2019) A mechanically-based model of snow slab and weak layer fracture in the Propagation Saw Test. International Journal of Solids and Structures 158, 120. doi: 10.1016/J.IJSOLSTR.2017.12.033CrossRefGoogle Scholar
Bergfeld, B and 9 others (2021) Crack propagation speeds in weak snowpack layers. Journal of Glaciology 68(269), 557570. doi: 10.1017/jog.2021.118CrossRefGoogle Scholar
Bobillier, G and 5 others (2021) Micro-mechanical insights into the dynamics of crack propagation in snow fracture experiments. Scientific Reports 11, 11711. doi: 10.1038/s41598-021-90910-3CrossRefGoogle Scholar
Conway, H and Abrahamson, J (1984) Snow stability index. Journal of Glaciology 30(106), 321327. doi: 10.3189/S002214300000616XCrossRefGoogle Scholar
Deems, JS, Fassnacht, SR and Elder, KJ (2006) Fractal distribution of snow depth from lidar data. Journal of Hydrometeorology 7(2), 285297. doi: 10.1175/JHM487.1CrossRefGoogle Scholar
Faillettaz, J, Louchet, F and Grasso, JR (2004) Two-threshold model for scaling laws of noninteracting snow avalanches. Physical review letters 93(20), 14. doi: 10.1103/PhysRevLett.93.208001CrossRefGoogle ScholarPubMed
Feick, S, Kronholm, K and Schweizer, J (2007) Field observations on spatial variability of surface hoar at the basin scale. Journal of Geophysical Research: Earth Surface 112(2), 116. doi: 10.1029/2006JF000587CrossRefGoogle Scholar
Föhn, P (1987) The stability index and various triggering mechanisms. IAHS 162, 195214.Google Scholar
Fyffe, B and Zaiser, M (2004) The effects of snow variability on slab avalanche release. Cold Regions Science and Technology 40(3), 229242. doi: 10.1016/j.coldregions.2004.08.004CrossRefGoogle Scholar
Gaume, J and Reuter, B (2017) Assessing snow instability in skier-triggered snow slab avalanches by combining failure initiation and crack propagation. Cold Regions Science and Technology 144, 615. doi: 10.1016/j.coldregions.2017.05.011CrossRefGoogle Scholar
Gaume, J, Chambon, G, Eckert, N and Naaim, M (2013) Influence of weak-layer heterogeneity on snow slab avalanche release: application to the evaluation of avalanche release depths. Journal of Glaciology 59(215), 423437. doi: 10.3189/2013JoG12J161CrossRefGoogle Scholar
Gaume, J and 6 others (2014) Evaluation of slope stability with respect to snowpack spatial variability. Journal of Geophysical Research: Earth Surface 119(9), 17831799. doi: 10.1002/2014jf003193CrossRefGoogle Scholar
Gaume, J, Chambon, G, Eckert, N, Naaim, M and Schweizer, J (2015) Influence of weak layer heterogeneity and slab properties on slab tensile failure propensity and avalanche release area. Cryosphere 9(2), 795804. doi: 10.5194/tc-9-795-2015CrossRefGoogle Scholar
Gaume, J, Van Herwijnen, A, Chambon, G, Wever, N and Schweizer, J (2017) Snow fracture in relation to slab avalanche release: critical state for the onset of crack propagation. Cryosphere 11(1), 217228. doi: 10.5194/tc-11-217-2017CrossRefGoogle Scholar
Gaume, J, Gast, T, Teran, J, van Herwijnen, A and Jiang, C (2018) Dynamic anticrack propagation in snow. Nature Communications 9(1), 110. doi: 10.1038/s41467-018-05181-wCrossRefGoogle ScholarPubMed
Gaume, J, van Herwijnen, A, Gast, T, Teran, J and Jiang, C (2019) Investigating the release and flow of snow avalanches at the slope-scale using a unified model based on the material point method. Cold Regions Science and Technology 168, 102847. doi: 10.1016/j.coldregions.2019.102847CrossRefGoogle Scholar
Gauthier, D and Jamieson, B (2008) Evaluation of a prototype field test for fracture and failure propagation propensity in weak snowpack layers. Cold Regions Science and Technology 51(2-3), 8797. doi: 10.1016/J.COLDREGIONS.2007.04.005CrossRefGoogle Scholar
Grünewald, T and 9 others (2013) Statistical modelling of the snow depth distribution in open alpine terrain. Hydrology and Earth System Sciences 17(8), 30053021. doi: 10.5194/hess-17-3005-2013CrossRefGoogle Scholar
Guillet, L, Blatny, L, Trottet, B and Gaume, J (2023) A Depth-Averaged Material Point Method for Shallow Landslides: Applications to Snow Slab Avalanche Release. Journal of Geophysical Research: Earth Surface 128(8), 128. doi: 10.1029/2023JF007092Google Scholar
Habermann, M, Schweizer, J and Jamieson, JB (2008) Influence of snowpack layering on human-triggered snow slab avalanche release. Cold Regions Science and Technology 54(3), 176182. doi: 10.1016/j.coldregions.2008.05.003CrossRefGoogle Scholar
Hägeli, P and McClung, DM (2004) Hierarchy theory as a conceptual framework for scale issues in avalanche forecast modeling. Annals of Glaciology 38(2016), 209214. doi: 10.3189/172756404781815266CrossRefGoogle Scholar
Hagenmuller, P, Chambon, G and Naaim, M (2015) Microstructure-based modeling of snow mechanics: a discrete element approach. The Cryosphere 9, 19691982. doi: 10.5194/tc-9-1969-2015CrossRefGoogle Scholar
Harvey, S, Rhyner, H and Schweizer, J (2023) Lawinen: Verstehen, Beurteilen und Risikobasiert Entscheiden. Bruckman, München.Google Scholar
Heierli, J, Gumbsch, P and Zaiser, M (2008) Anticrack nucleation as triggering mechanism for snow slab avalanches. Science 321(5886), 240243. doi: 10.1126/science.1153948CrossRefGoogle ScholarPubMed
Hubbard, A and 6 others (2018) The seasonal snow cover dynamics: review on wind-driven coupling processes. Frontiers in Earth Science 6, 125. doi: 10.3389/feart.2018.00197Google Scholar
Jamieson, J and Johnston, C (1990) In-situ tensile tests of snow-pack layers. Journal of Glaciology 36(122), 102106. doi: 10.3189/S002214300000561XCrossRefGoogle Scholar
Johnson, JB and Schneebeli, M (1999) Characterizing the microstructural and micromechanical properties of snow. Cold Regions Science and Technology 30(1-3), 91100. doi: 10.1016/S0165-232X(99)00013-0CrossRefGoogle Scholar
Kronholm, K (2004) Spatial variability of snow mechanical properties with regard to avalanche formation. Ph.D. thesis, University of Zurich, Zurich.Google Scholar
Kronholm, K and Birkeland, KW (2005) Integrating spatial patterns into a snow avalanche cellular automata model. Geophysical Research Letters 32(19), 15. doi: 10.1029/2005GL024373CrossRefGoogle Scholar
Kronholm, K and Birkeland, KW (2007) Reliability of sampling designs for spatial snow surveys. Computers and Geosciences 33(9), 10971110. doi: 10.1016/j.cageo.2006.10.004CrossRefGoogle Scholar
Kronholm, K and Schweizer, J (2003) Snow stability variation on small slopes. Cold Regions Science and Technology 37(3), 453465. doi: 10.1016/S0165-232X(03)00084-3CrossRefGoogle Scholar
Kronholm, K, Schweizer, J, Schneebeli, M and Pielmeier, C (2004) Spatial variability of snowpack stability on small slopes studied with the stuffblock test. Data of Glaciological studie 97, 180188.Google Scholar
Landry, C and 5 others (2004) Variations in snow strength and stability on uniform slopes. Cold Regions Science and Technology 39(2-3), 205218. doi: 10.1016/j.coldregions.2003.12.003CrossRefGoogle Scholar
Löwe, H and van Herwijnen, A (2012) A Poisson shot noise model for micro-penetration of snow. Cold Regions Science and Technology 70, 6270. doi: 10.1016/j.coldregions.2011.09.001CrossRefGoogle Scholar
Lutz, E and Birkeland, KW (2011) Spatial patterns of surface hoar properties and incoming radiation on an inclined forest opening. Journal of Glaciology 57(202), 355366. doi: 10.3189/002214311796405843CrossRefGoogle Scholar
Lutz, E, Birkeland, KW, Kronholm, K, Hansen, K and Aspinall, R (2007) Surface hoar characteristics derived from a snow micropenetrometer using moving window statistical operations. Cold Regions Science and Technology 47(1-2 SPEC. ISS), 118133. doi: 10.1016/j.coldregions.2006.08.021CrossRefGoogle Scholar
McClung, DM (1981) Fracture mechanical models of dry slab avalanche release. Journal of Geophysical Research: Solid Earth 86(B11), 1078310790. doi: 10.1029/JB086IB11P10783CrossRefGoogle Scholar
McClung, DM (2009) Dimensions of dry snow slab avalanches from field measurements. Journal of Geophysical Research: Earth Surface 114(1), 110. doi: 10.1029/2007JF000941CrossRefGoogle Scholar
Mede, T, Chambon, G, Nicot, F and Hagenmuller, P (2020) Micromechanical investigation of snow failure under mixed-mode loading. International Journal of Solids and Structures 199, 95108. doi: 10.1016/J.IJSOLSTR.2020.04.020CrossRefGoogle Scholar
Meloche, F, Gauthier, F and Langlois, A (2023) Snow mechanical properties variability at the slope scale, implication for snow mechanical modeling. Preprint EGUsphere. doi: 10.5194/egusphere-2023-1586CrossRefGoogle Scholar
Miller, ZS, Peitzsch, EH, Sproles, EA, Birkeland, KW and Palomaki, RT (2022) Assessing the seasonal evolution of snow depth spatial variability and scaling in complex mountain terrain. Cryosphere 16(12), 49074930. doi: 10.5194/TC-16-4907-2022CrossRefGoogle Scholar
Monti, F, Gaume, J, Van Herwijnen, A and Schweizer, J (2016) Snow instability evaluation: calculating the skier-induced stress in a multi-layered snowpack. Natural Hazards and Earth System Sciences 16(3), 775788. doi: 10.5194/nhess-16-775-2016CrossRefGoogle Scholar
Mott, R, Schirmer, M and Lehning, M (2011) Scaling properties of wind and snow depth distribution in an Alpine catchment. Journal of Geophysical Research Atmospheres 116(6), 18. doi: 10.1029/2010JD014886CrossRefGoogle Scholar
Müller, S, Schüler, L, Zech, A and Heße, F (2022) GSTools v1.3: a toolbox for geostatistical modelling in Python. Geoscientific Model Development 15(7), 31613182. doi: 10.5194/GMD-15-3161-2022CrossRefGoogle Scholar
Proksch, M, Löwe, H and Schneebeli, M (2015) Density, specific surface area, and correlation length of snow measured by high-resolution penetrometry. Journal of Geophysical Research: Earth Surface 120(2), 346362. doi: 10.1002/2014JF003266CrossRefGoogle Scholar
Reuter, B, Richter, B and Schweizer, J (2016) Snow instability patterns at the scale of a small basin. Journal of Geophysical Research: Earth Surface 121(2), 257282. doi: 10.1002/2015JF003700CrossRefGoogle Scholar
Reuter, B, Proksch, M, Löwe, H, Van Herwijnen, A and Schweizer, J (2019) Comparing measurements of snow mechanical properties relevant for slab avalanche release. Journal of Glaciology 65(249), 5567. doi: 10.1017/jog.2018.93CrossRefGoogle Scholar
Scapozza, C, Bucher, F, Amann, P, Ammann, WJ and Bartelt, P (2004) The temperature- and density-dependent acoustic emission response of snow in monoaxial compression tests. Annals of Glaciology 38, 291298. doi: 10.3189/172756404781814861CrossRefGoogle Scholar
Schirmer, M, Wirz, V, Clifton, A and Lehning, M (2011) Persistence in intra-annual snow depth distribution: 1. Measurements and topographic control. Water Resources Research 47(9), 116. doi: 10.1029/2010WR009426Google Scholar
Schweizer, J, Jamieson, JB and Schneebeli, M (2003) Snow avalanche formation. Reviews of Geophysics 41(4), 125. doi: 10.1029/2002RG000123CrossRefGoogle Scholar
Schweizer, J, Kronholm, K, Jamieson, JB and Birkeland, KW (2008) Review of spatial variability of snowpack properties and its importance for avalanche formation. Cold Regions Science and Technology 51(2-3), 253272. doi: 10.1016/j.coldregions.2007.04.009CrossRefGoogle Scholar
Schweizer, J, Reuter, B, van Herwijnen, A and Gaume, J (2016) Avalanche release 101. In International Snow Science Workshop, Breckenridge, Colorado, Breckenridge, pp. 1–11.Google Scholar
Sigrist, C (2006) Measurement of fracture mechanical properties of snow and application to dry snow slab avalanche release. Ph.D. thesis, ETH Zürich, Zürich. doi: 10.3929/ETHZ-A-005282374.CrossRefGoogle Scholar
Skøien, JO and Blöschl, G (2006) Sampling scale effects in random fields and implications for environmental monitoring. Environmental Monitoring and Assessment 114(1-3), 521552. doi: 10.1007/s10661-006-4939-zCrossRefGoogle ScholarPubMed
Statham, G and 9 others (2018) A conceptual model of avalanche hazard. Natural Hazards 90(2), 663691. doi: 10.1007/s11069-017-3070-5CrossRefGoogle Scholar
Stethem, C and 5 others (2003) Snow avalanche hazard in Canada – a review. Natural Hazards 28(2-3), 487515. doi: 10.1023/A:1022998512227CrossRefGoogle Scholar
Sulsky, D, Chen, Z and Schreyer, HL (1994) A particle method for history-dependent materials. Computer Methods in Applied Mechanics and Engineering 118(1-2), 179196. doi: 10.1016/0045-7825(94)90112-0CrossRefGoogle Scholar
Techel, F and 7 others (2016) Avalanche fatalities in the European Alps: Long-term trends and statistics. Geographica Helvetica 71(2), 147159. doi: 10.5194/gh-71-147-2016CrossRefGoogle Scholar
Techel, F, Karsten, M and Schweizer, J (2020) On the importance of snowpack stability, the frequency distribution of snowpack stability, and avalanche size in assessing the avalanche danger level. Cryosphere 14(10), 35033521. doi: 10.5194/TC-14-3503-2020CrossRefGoogle Scholar
Trottet, B and 6 others (2022) Transition from sub-Rayleigh anticrack to supershear crack propagation in snow avalanches. Nature Physics 18(9), 10941098. doi: 10.1038/s41567-022-01662-4CrossRefGoogle ScholarPubMed
van Herwijnen, A and Jamieson, B (2007) Snowpack properties associated with fracture initiation and propagation resulting in skier-triggered dry snow slab avalanches. Cold Regions Science and Technology 50(1-3), 1322. doi: 10.1016/J.COLDREGIONS.2007.02.004CrossRefGoogle Scholar
Winstral, A, Elder, K and Davis, RE (2002) Spatial snow modeling of wind-redistributed snow using terrain-based parameters. Journal of Hydrometeorology 3(5), 524538. doi: 10.1175/1525-7541(2002)003<0524:SSMOWR>2.0.CO;22.0.CO;2>CrossRefGoogle Scholar
Figure 0

Figure 1. Example of one realization of a Gaussian Random Field GRF for slab depth D, slab density ρ, skier crack length lsk, critical crack length ac, skier propagation index SPI and skier tracks with SPI. The slope is reduced to 50 m by 100 m only for visualization purposes.

Figure 1

Figure 2. DAMPM model and simulation parameters. (a) The geometry of the simulated propagation saw test PST with a sinusoidal slab depth variation and shear strength associated. The slab depth variation parameters from the sinus function are the mean slab depth $\overline {D}$, the standard deviation SD, and the correlation length $\epsilon$. (b) Slab elastoplasticity model following a Modified Cam-Clay yield surface. (c) Weak-layer model as quasi-brittle interface.

Figure 2

Figure 3. Sensitivity analysis for the mean skier-triggering probability with regards to the mean, spatial variance and correlation length of the slab depth. The mean probability is computed from a distribution of 100 realizations for each specific set of mean slab depth, variance and correlation length.

Figure 3

Figure 4. Probability density function of the skier-triggering probability for mid to low mean skier-triggering probability. All the distributions presented are from a GRF using a 0.7 m mean slab depth, 0.0025–0.0075 m2 slab depth variance, and 10-20-30 m correlation length.

Figure 4

Figure 5. Mean skier-triggering probability from 100 realizations for different skiing style ratios Across/Rdown. Across represents the cross-slope amplitude and Rdown represents the down-slope turn radius. A small skiing style ratio represents a linear down-slope trajectory and a large skiing style ratio represents a cross-slope trajectory. The probabilities are constrained by two values: the first is a probability of 1 where all skiers have triggered, and the second value is a linear weak spot cross-slope ratio between the sum of weak spot length in the cross-slope direction compared to the total cross-slope length. The dashed line is set at 0.505 which is the mean of the linear weak spot cross-slope ratio for 100 realizations for this set of GRF parameters: mean slab depth of 0.7 m, variance of 0.0075 m2, and 20 m correlation length. This line should move with regard to the GRF parameters. The inlets represent schematic skiing style based on the skiing style ratios.

Figure 5

Figure 6. Experimental cumulative density functions (ECDF) of the number of additional skier to trigger from mid to low mean probability. All the distributions presented are from a GRF using a 0.7 m mean slab depth, 0.005 m2 slab depth variance, and 5-10-20-30 m correlation lengths. The inlets show examples of the corresponding SPI map specific to their GRF parameters.

Figure 6

Figure 7. Three different regimes of tensile fracture for a 0.7 m slab depth $\overline {D}$ and 0.25 m SD. These three simulations show the last frame saved just before the tensile fracture occurs when σxx = σt. The shear stress τxz and the weak layer shear strength τp and the cohesion c are also represented. The crack tip (dotted line) is located just behind the peak of τxz at the loss of cohesion c. The distance between the crack tip and the τxz peak is due to the softening δ. The bottom plot shows the corresponding crack speed $\dot {a}$ which is normalized over the shear wave speed $C_s = \sqrt {{G}/{\rho }}$, and the slab depth D in m. (a) PST simulation with a $\epsilon$ 30 m just before a tensile fracture occurs. (b) PST simulation with a $\epsilon$ of 15 m just before a tensile fracture occurs. (c) PST simulation with a $\epsilon$ of 10 m just before a tensile fracture occurs.

Figure 7

Figure 8. Sensitivity analysis for the tensile length Lt with regards to the mean $\overline {D}$, standard deviation SD and correlation length $\epsilon$ of the slab depth sinus function.

Figure 8

Figure 9. Probability density functions of tensile lengths Lt of 50 realizations for different mean slab depths $\overline {D}$ of 0.5–1 m, different variances $S^2_D$ of 0.005–0.025 m2, and 5–15–30 m correlation lengths $\epsilon$. The dashed line represents the homogeneous tensile length for a mean slab depth of 0.5 m and 1 m.

Figure 9

Figure 10. Probability of skier-triggering and normalized potential avalanche release size in relation to the mean slab depth and standard deviation of the slab depth. Potential avalanche release size combines the tensile length normalized with the largest tensile length multiplied by the mean slab depth. We show the standard deviation slab depth values for visual purposes but the variance values used with GRF method yield approximately the same values as the standard deviation slab depth used with the sinus function.

Figure 10

Figure 11. Convergence of the total number of skiers used to compute the probability of skier-triggering for GRF parameters of 0.7  m mean slab depth, 0.0075 m2 variance and 20 m correlation length. The blue line shows the convergence of the mean after 100 realizations and the orange line shows the standard deviation after 100 realizations.

Figure 11

Figure 12. Two different regimes of tensile fracture for a 0.7 m slab depth $\overline {D}$ and 0.025 m variance $S^2_D$. These three simulations show the last frame saved just before the tensile fracture occurs when σxx = σt. The shear stress τxz and the weak layer shear strength τp and the cohesion c are also represented. The crack tip (dotted line) is located just behind the peak of τxz at the loss of cohesion c. The distance between the crack tip and the τxz peak is due to the softening δ. The bottom plot shows the corresponding crack speed $\dot {a}$ which is normalized over the shear wave speed $C_s = \sqrt {G/\rho }$, and the slab depth D in m. (a) PST simulation with a $\epsilon$ of 30 m just before a tensile fracture occurs. (b) PST simulation using GRF with a $\epsilon$ of 5 m just before a tensile fracture occurs.