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Quantification of basal friction for glide-snow avalanche mitigation measures in forested and non-forested terrain (2014)

Feistl, T. ; Bebi, P. ; Dreier, L. ; [et al.]

Copernicus

In: Natural Hazards and Earth System Sciences Discussions. 2014; 2(4): 2947-2980. Published 2014 Apr 29. doi: 10.5194/nhessd-2-2947-2014.

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Publication Date: 2014-04-29

Description: A long-standing problem in avalanche engineering is to design defense structures and manage forest stands such that they can withstand the forces of the natural snow cover. In this way glide-snow avalanches can be prevented. Ground friction plays a crucial role in this process. To verify existing guidelines, we collected data on the vegetation cover and terrain characteristics of 101 glide-snow release areas in Davos, Switzerland. We quantified the Coulomb friction parameter μ by applying a physical model that accounts for the dynamic forces of the moving snow on the stauchzone. We investigated the role of glide length, slope steepness and friction on avalanche release. Our calculations revealed that the slope angle and slab length for smooth slopes corresponds to the technical guidelines for defense structure distances in Switzerland. Artificial defense structures, built in accordance with guidelines, prevent glide-snow avalanche releases, even when the terrain is smooth. Slopes over 40 m length and 45° steepness require a ground friction of μ = 0.7 corresponding to stumps or tree regeneration to assure protection. Forest management guidelines which define maximum forest gap sizes to prevent glide-snow avalanche release neglect the role of surface roughness and therefore underestimate the danger on smooth slopes.

Electronic ISSN: 2195-9269

Topics: Geography , Geosciences

Published by Copernicus on behalf of European Geosciences Union.

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Forest damage and snow avalanche flow regime (2015)

Feistl, T. ; Bebi, P. ; Christen, M. ; [et al.]

Copernicus

In: Natural Hazards and Earth System Sciences Discussions. 2015; 3(1): 535-574. Published 2015 Jan 20. doi: 10.5194/nhessd-3-535-2015.

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Publication Date: 2015-01-20

Description: Snow avalanches break, uproot and overturn trees causing damage to forests. The extent of forest damage provides useful information on avalanche frequency and intensity. However, impact forces depend on avalanche flow regime. In this paper, we define avalanche loading cases representing four different avalanche flow regimes: powder, intermittent, dry and wet. In the powder regime, the blast of the cloud can produce large bending moments in the tree stem because of the impact area extending over the entire tree crown. We demonstrate that intermittent granular loadings are equivalent to low-density uniform dry snow loadings under the assumption of homogeneous particle distributions. In the wet snow case, avalanche pressure is calculated using a quasi-static model accounting for the motion of plug-like wet snow flows. Wet snow pressure depends both on avalanche volume and terrain features upstream of the tree. Using a numerical model that simulates both powder and wet snow avalanches, we study documented events with forest damage. We find (1) powder clouds with velocities over 20 m s−1 can break tree stems, (2) the intermittent regime seldom controls tree breakage and (3) quasi-static pressures of wet snow avalanches can be much higher than pressures calculated using dynamic pressure formulas.

Electronic ISSN: 2195-9269

Topics: Geography , Geosciences

Published by Copernicus on behalf of European Geosciences Union.

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Computational snow avalanche simulation in forested terrain (2013)

Teich, M. ; Fischer, J.-T. ; Feistl, T. ; [et al.]

Copernicus

In: Natural Hazards and Earth System Sciences Discussions. 2013; 1(5): 5561-5601. Published 2013 Oct 16. doi: 10.5194/nhessd-1-5561-2013.

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Publication Date: 2013-10-16

Description: Two-dimensional avalanche simulation software operating in three-dimensional terrain is widely used for hazard zoning and engineering to predict runout distances and impact pressures of snow avalanche events. Mountain forests are an effective biological protection measure; however, the protective capacity of forests to decelerate or even to stop avalanches that start within forested areas or directly above the treeline is seldom considered in this context. In particular, runout distances of small- to medium-scale avalanches are strongly influenced by the structural conditions of forests in the avalanche path. We present an evaluation and improvement of a novel forest detrainment function implemented in the avalanche simulation software RAMMS for avalanche simulation in forested terrain. The new approach accounts for the effect of forests in the avalanche path by detraining mass, which leads to a deceleration and runout shortening of avalanches. The relationship is parameterized by the detrainment coefficient K (Pa) accounting for differing forest characteristics. We varied K when simulating 40 well-documented small- to medium-scale avalanches which released in and ran through forests of the Swiss Alps. Analyzing and comparing observed and simulated runout distances statistically revealed values for K suitable to simulate the combined influence of four forest characteristics on avalanche runout: forest type, crown closure, vertical structure and surface roughness, e.g. values for K were higher for dense spruce and mixed spruce-beech forests compared to open larch forests at the upper treeline. Considering forest structural conditions within avalanche simulation will improve current applications for avalanche simulation tools in mountain forest and natural hazard management.

Electronic ISSN: 2195-9269

Topics: Geography , Geosciences

Published by Copernicus on behalf of European Geosciences Union.

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Quantification of basal friction for technical and silvicultural glide-snow avalanche mitigation measures (2014)

Feistl, T. ; Bebi, P. ; Dreier, L. ; [et al.]

Copernicus

In: Natural Hazards and Earth System Sciences. 2014; 14(11): 2921-2931. Published 2014 Nov 07. doi: 10.5194/nhess-14-2921-2014.

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Publication Date: 2014-11-07

Description: A long-standing problem in avalanche engineering is to design defense structures and manage forest stands such that they can withstand the forces of the natural snow cover. In this way, glide-snow avalanches can be prevented. Ground friction plays a crucial role in this process. To verify existing guidelines, we collected data on the vegetation cover and terrain characteristics of 101 glide-snow release areas in Davos, Switzerland. We quantified the Coulomb friction parameter μm by applying a physical model that accounts for the dynamic forces of the moving snow in the stauch zone. We investigated the role of glide length, slope steepness and friction in avalanche release. Our calculations revealed that the slope angle and slab length for smooth slopes correspond to the technical guidelines for defense structure distances in Switzerland. Artificial defense structures, built in accordance with guidelines, prevent glide-snow avalanche releases, even when the terrain is smooth. Slopes over 40 m in length and 45° in steepness require a ground friction of μm = 0.7 corresponding to stumps or tree regeneration to ensure protection. Forest management guidelines that define maximum forest gap sizes to prevent glide-snow avalanche release neglect the role of surface roughness and therefore underestimate the danger on smooth slopes.

Print ISSN: 1561-8633

Electronic ISSN: 1684-9981

Topics: Geography , Geosciences

Published by Copernicus on behalf of European Geosciences Union.

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Computational snow avalanche simulation in forested terrain (2014)

Teich, M. ; Fischer, J.-T. ; Feistl, T. ; [et al.]

Copernicus

In: Natural Hazards and Earth System Sciences. 2014; 14(8): 2233-2248. Published 2014 Aug 27. doi: 10.5194/nhess-14-2233-2014.

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Publication Date: 2014-08-27

Description: Two-dimensional avalanche simulation software operating in three-dimensional terrain is widely used for hazard zoning and engineering to predict runout distances and impact pressures of snow avalanche events. Mountain forests are an effective biological protection measure against avalanches; however, the protective capacity of forests to decelerate or even to stop avalanches that start within forested areas or directly above the treeline is seldom considered in this context. In particular, runout distances of small- to medium-scale avalanches are strongly influenced by the structural conditions of forests in the avalanche path. We present an evaluation and operationalization of a novel detrainment function implemented in the avalanche simulation software RAMMS for avalanche simulation in forested terrain. The new approach accounts for the effect of forests in the avalanche path by detraining mass, which leads to a deceleration and runout shortening of avalanches. The relationship is parameterized by the detrainment coefficient K [kg m−1 s−2] accounting for differing forest characteristics. We varied K when simulating 40 well-documented small- to medium-scale avalanches, which were released in and ran through forests of the Swiss Alps. Analyzing and comparing observed and simulated runout distances statistically revealed values for K suitable to simulate the combined influence of four forest characteristics on avalanche runout: forest type, crown closure, vertical structure and surface cover, for example, values for K were higher for dense spruce and mixed spruce-beech forests compared to open larch forests at the upper treeline. Considering forest structural conditions within avalanche simulations will improve current applications for avalanche simulation tools in mountain forest and natural hazard management.

Print ISSN: 1561-8633

Electronic ISSN: 1684-9981

Topics: Geography , Geosciences

Published by Copernicus on behalf of European Geosciences Union.

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6

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Forest damage and snow avalanche flow regime (2015)

Feistl, T. ; Bebi, P. ; Christen, M. ; [et al.]

Copernicus

In: Natural Hazards and Earth System Sciences. 2015; 15(6): 1275-1288. Published 2015 Jun 18. doi: 10.5194/nhess-15-1275-2015.

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Publication Date: 2015-06-18

Description: Snow avalanches break, uproot and overturn trees causing damage to forests. The extent of forest damage provides useful information on avalanche frequency and intensity. However, impact forces depend on avalanche flow regime. In this paper, we define avalanche loading cases representing four different avalanche flow regimes: powder, intermittent, dry and wet. Using a numerical model that simulates both powder and wet snow avalanches, we study documented events with forest damage. First we show that in the powder regime, although the applied impact pressures can be small, large bending moments in the tree stem can be produced due to the torque action of the blast. The impact area of the blast extends over the entire tree crown. We find that, powder clouds with velocities over 20 m s-1 can break tree stems. Second we demonstrate that intermittent granular loadings are equivalent to low-density uniform dry snow loadings under the assumption of homogeneous particle distributions. The intermittent regime seldom controls tree breakage. Third we calculate quasi-static pressures of wet snow avalanches and show that they can be much higher than pressures calculated using dynamic pressure formulas. Wet snow pressure depends both on avalanche volume and terrain features upstream of the tree.

Print ISSN: 1561-8633

Electronic ISSN: 1684-9981

Topics: Geography , Geosciences

Published by Copernicus on behalf of European Geosciences Union.

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