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The role of stress concentration in slab avalanche release: comments on Dr R. A. Sommerfeld's paper

Published online by Cambridge University Press:  30 January 2017

Charles C. Bradley
Affiliation:
Department of Earth Sciences, Montana State University, Bozeman, Montana 59715, U.S.A.
Duain Bowles
Affiliation:
Department of Earth Sciences, Montana State University, Bozeman, Montana 59715, U.S.A.
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Abstract

Type
Correspondence
Copyright
Copyright © International Glaciological Society 1970

The Editor,

Journal of Glaciology

Sir,

Dr Sommerfeld has given us some interesting and useful ideas to carry into the field—especially in the area of interpreting fracture patterns at the starting zone of avalanches. In developing his own theory of slab avalanche release, Sommerfeld rejects our theory of basal collapse (Reference BradleyBradley, 1966; Reference Bradley, Bowles and ÖuraBradley and Bowles, 1967). He concludes that collapse is an unlikely or at best an unimportant mechanism for avalanche release. We take this rejection as an invitation to respond.

We will not debate Sommerfeld's theory. It looks sound enough as a model for wind-slab release and similar avalanches. However, it seems not to explain what has been going on now in the Bridger Range of Montana for the last month and off and on for 11 years of observation. Since late December this season we have had over a dozen large, full-depth avalanches of the classic climax pattern. In a number of different ways these avalanches have been closely associated with snow-pack collapse. While the association does not prove causal connections it at least suggests that the collapsing condition might have some importance in the scheme of things. The following summary of this year's field notes explains a little of the nature of the association.

There have been five personal encounters this season with massive snow-pack collapse in which avalanches did not follow. In these the snow pack ranged in thickness from 1 to 2.5 m. The fracture system cut across the pack for distances of 50 to 100 m. The fractures showed vertical displacement ranging from a few millimeters to 1.5 cm and were accompanied by a substantial sonic shock. There was no perceptible lateral movement in any of the five. Slope angles ranged from about 30° to nearly horizontal. Two pit studies showed the slab fracture to terminale in the weak zone at the base. The angle of the fracture indicated tensile fracture of the slab without regard to slope angle. (One pit was on the flat, one was on the 30° slope.) Strength-to-load ratios were taken at the weakest zone just above the base of the pack immediately prior to three of the events. These ratios were 1.5, 1.8, 1.7. We view the snow-pack system in these events to be like a broad platform supported by columns. If the pillars are too weak or the platform overloaded in a certain area the pillars beneath fail under compression and the platform fails by tension.

Both in general seasonal timing and in slope orientation (east to north-east facing) the collapses correlated closely with the avalanche events. Two of the five collapse events occurred very close to starting zones. (We agree with Sommerfeld that a collapse at the foot of the slope or out on the flat probably does not cause many avalanches.)

There is still closer association of snow-pack collapse with the avalanches. The starting zones of three of the avalanches were visited shortly after release. In all three there were fractures above the breakaway scarps which indicated that this upper portion of the snow pack had dropped vertically about the same time as the avalanche ran but it had not moved laterally. Resistograms taken above the fracture of one of these showed strength/load ratio 1.6 at the weak zone.

This kind of evidence for snow-pack collapse closely associated with some of our biggest and most destructive avalanches we find at least very interesting. We therefore tentatively conclude that whether or not snow pack collapse is important probably depends on what you are studying and where you are standing when it lets go.

28 January 1970

References

Bradley, C.C. 1966 The snow resistograph and slab avalanche investigations. Union de Géodésie el Géophysique Internationale. Association Internationale d'Hydrologie Scientifique. Commission pour la Neige et la Glace. Division Neige Saisonnière et Avalanches, Symposium international sur les aspects scientifiques des avalanches de neige, 5–10 avril 1965 Davos, Suisse, p. 35160. Google Scholar
Bradley, C.C. Bowles, D. 1967 Strength–load ratio. An index of deep slab avalanche conditions, (In Öura, H. ed. Physics of snow and ice: international conference on low temperature science.… 1966 … Proceedings, Vol. I, Pt. 2. [Sapporo], Institute of Low Temperature Science, Hokkaido University p. 124353.) Google Scholar
Sommerfeld, R.A. 1969 The role of stress concentration in slab avalanche release. Journal of Glaciology Vol. 8, No. 54, p. 45162 CrossRefGoogle Scholar