From sub-Rayleigh to intersonic crack propagation in snow slab avalanche release

Trottet, Bertil; Simenhois, Ron; Bobillier, Grégoire; Herwijnen, Alec van; Jiang, Chenfanfu; Gaume, Johan

doi:10.5194/egusphere-egu21-8253

Cited by 2 publications

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“…Crack speeds from PSTs are in line with theoretical predictions of incipient shear cracks (McClung, 2005) and asymptotic flexural speeds (Heierli, 2005). However, much higher crack speeds have been estimated as well (Hamre et al, 2014;Gaume et al, 2019;Trottet et al, 2021). This highlights again that reported PSTs do not cover the full parameter space, especially in terms of PST length.…”

Section: Introductionsupporting

confidence: 76%

Dynamic crack propagation in weak snowpack layers: insights from high-resolution, high-speed photography

Bergfeld¹,

Herwijnen²,

Reuter

et al. 2021

The Cryosphere

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Abstract. Dynamic crack propagation in snow is of key importance for avalanche release. Nevertheless, it has received very little experimental attention. With the introduction of the propagation saw test (PST) in the mid-2000s, a number of studies have used particle tracking analysis of high-speed video recordings of PST experiments to study crack propagation processes in snow. However, due to methodological limitations, these studies have provided limited insight into dynamical processes such as the evolution of crack speed within a PST or the touchdown distance, i.e. the length from the crack tip to the trailing point where the slab comes to rest on the crushed weak layer. To study such dynamical effects, we recorded PST experiments using a portable high-speed camera with a horizontal resolution of 1280 pixels at rates of up to 20 000 frames s−1. We then used digital image correlation (DIC) to derive high-resolution displacement and strain fields in the slab, weak layer and substrate. The high frame rates enabled us to calculate time derivatives to obtain velocity and acceleration fields. We demonstrate the versatility and accuracy of the DIC method by showing measurements from three PST experiments, resulting in slab fracture, crack arrest and full propagation. We also present a methodology to determine relevant characteristics of crack propagation, namely the crack speed (20–30 m s−1), its temporal evolution along the column and touchdown distance (2.7 m) within a PST, and the specific fracture energy of the weak layer (0.3–1.7 J m−2). To estimate the effective elastic modulus of the slab and weak layer as well as the weak layer specific fracture energy, we used a recently proposed mechanical model. A comparison to already-established methods showed good agreement. Furthermore, our methodology provides insight into the three different propagation results found with the PST and reveals intricate dynamics that are otherwise not accessible.

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Section: Introductionsupporting

confidence: 76%

Dynamic crack propagation in weak snowpack layers: insights from high-resolution, high-speed photography

Bergfeld¹,

Herwijnen²,

Reuter

et al. 2021

The Cryosphere

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View full text Add to dashboard Cite

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Crack propagation speeds in weak snowpack layers

Bergfeld¹,

Herwijnen²,

Bobillier³

et al. 2021

J. Glaciol.

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For the release of a slab avalanche, crack propagation within a weak snowpack layer below a cohesive snow slab is required. As crack speed measurements can give insight into underlying processes, we analysed three crack propagation events that occurred in similar snowpacks and covered all scales relevant for avalanche release. For the largest scale, up to 400 m, we estimated crack speed from an avalanche movie; for scales between 5 and 25 m, we used accelerometers placed on the snow surface and for scales below 5 m, we performed a propagation saw test. The mean crack speeds ranged from 36 ± 6 to 49 ± 5 m s−1, and did not exhibit scale dependence. Using the discrete element method and the material point method, we reproduced the measured crack speeds reasonably well, in particular the terminal crack speed observed at smaller scales. Finally, we used a finite element model to assess the speed of different elastic waves in a layered snowpack. Results suggest that the observed cracks propagated as mixed mode closing cracks and that the flexural wave of the slab is responsible for the energy transfer to the crack tip.

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From sub-Rayleigh to intersonic crack propagation in snow slab avalanche release

Cited by 2 publications

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Dynamic crack propagation in weak snowpack layers: insights from high-resolution, high-speed photography

Dynamic crack propagation in weak snowpack layers: insights from high-resolution, high-speed photography

Crack propagation speeds in weak snowpack layers

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