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Abstract
Snow avalanches are common phenomena in western orway. During the winter–spring period 2011/2012 an extreme snow avalanche occurred within the upper valley part of a steep and glacier‐connected mountain catchment (ødalen) in western orway. Compared with annually occurring regular snow avalanches, so‐called ‘extreme snow avalanche events’ are more difficult to monitor and to study as they are characterized by recurrence intervals often longer than a decade. Morphometric and meteorological controls of a high‐magnitude/low‐frequency snow avalanche event, its geomorphic effects as well as its related relative role in mass transport compared with the annually monitored snow avalanche activity within the ødalen catchment were explored. Maximum values of snow height, velocity and pressure were predicted by applying a numerical run‐out simulation. The formation of this snow avalanche resulted from the combination of extraordinary meteorological conditions and a favourable morphometric setting of the source area. The snow avalanche path covered a total distance of 2900 m, including a stretch of 850 m where the snow avalanche slid downwards on top of the Bødalsbreen outlet glacier. Within the run‐out zone, directly located in front of the ødalen outlet glacier, 2032 stones with b‐axes >5 cm were remobilized which corresponds to a total transferred debris mass of 460 t. Compared with annually occurring snow avalanches within the ødalen drainage basin the relative importance of extreme‐sized snow avalanches is comparably low with respect to direct erosion and sediment transfer along rockwalls at higher slope areas. However, extreme‐sized snow avalanches play a significant role with respect to the remobilization of debris/sediment at lower slope areas as well as to down‐valley transport of sediment, including recognizable transfers of debris into the main stream channels of the drainage basin system whenever extreme snow avalanches reach the main channel.
Acknowledgements
The presented research has been funded by the Geological Survey of Norway (NGU) and by the Norwegian Research Council (NFR) (grant 193358/V30 SedyMONT‐Norway, to A.A. Beylich). We would like to thank Marc Christen (Davos, Switzerland) for his technical support with the RAMMS:AVALANCHE model. Magne Beinnes (Loen, Norway) is acknowledged for local logistical support during fieldwork. We thank the two anonymous reviewers for their helpful comments improving this paper.
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Katja Laute
Katja Laute, Achim A. Beylich, Geological Survey of Norway (NGU), Geo‐Environment Division, P.O. Box 6315 Sluppen, NO‐7491 Trondheim, Norway
E‐mail: [email protected]; [email protected]