Abstract
In mountain areas, mass movements, such as hillslope debris flows, pose a serious threat to people and infrastructure, although size and runout distances are often smaller than those of debris avalanches or in-channel-based processes like debris floods or debris flows. Hillslope debris-flow events can be regarded as a unique process that generally can be observed at steep slopes. The delimitation of endangered areas and the implementation of protective measures are therefore an important instrument within the framework of a risk analysis, especially in the densely populated area of the alpine region. Here, two-dimensional runout prediction methods are helpful tools in estimating possible travel lengths and affected areas. However, not many studies focus on 2D runout estimations specifically for hillslope debris-flow processes. Based on data from 19 well-documented hillslope debris-flow events in Switzerland, we performed a systematic evaluation of runout simulations conducted with the software Rapid Mass Movement Simulation: Debris Flow (RAMMS DF)—a program originally developed for runout estimation of debris flows and snow avalanches. RAMMS offers the possibility to use a conventional Voellmy-type shear stress approach to describe the flow resistance as well as to consider cohesive interaction as it occurs in the core of dense flows with low shear rates, like we also expect for hillslope debris-flow processes. The results of our study show a correlation between the back-calculated dry Coulomb friction parameters and the percentage of clay content of the mobilised soils. Considering cohesive interaction, the performance of all simulations was improved in terms of reducing the overestimation of the observed deposition areas. However, the results also indicate that the parameter which accounts for cohesive interaction can neither be related to soil physical properties nor to different saturation conditions.
Highlights
Mountain areas are especially prone to flow and slide processes of different mass movements because of their high relief energies
The a priori estimation of process parameters as well as the magnitude of hillslope processes is typically associated with large uncertainties
Data of 19 well-documented hillslope debris-flow events in Switzerland were used for this study
Summary
Mountain areas are especially prone to flow and slide processes of different mass movements because of their high relief energies. To reduce the damage to people and infrastructure caused by hillslope debris-flow events, endangered areas have to be known and mitigation measures are necessary. To this end, initiation areas of shallow slides and associated hillslope debris flows can often be reliably identified, e.g., in [2,3,4,5]. 2D runout simulation models have proven to be suitable tools for creating detailed delineation of typical mass movement deposits in torrent catchments, e.g., in [6,7,8,9,10,11], supporting the development of hazard maps and the estimation. The a priori estimation of process parameters as well as the magnitude of hillslope processes is typically associated with large uncertainties
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