The scaling of landslide-dammed lakes

The scaling of landslide-dammed lakes

The size-frequency distributions of earth surface processes and landforms are often characterized by power-law scaling, indicating invariance over certain scale ranges. Determining such characteristic scaling improved the understanding and prediction of landslide occurrence. However, the scaling of...

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Bibliographic Details
Published in:Global and planetary change Vol. 228; p. 104190
Main Authors: Argentin, Anne-Laure, Prasicek, Günther, Robl, Jörg, Hergarten, Stefan, Hölbling, Daniel, Abad, Lorena, Dabiri, Zahra
Format: Journal Article
Language:English
Published: Elsevier B.V 01-09-2023
Subjects:
Cascading hazards
Landslide
Landslide dam
Landslide-dammed lake
Natural Hazard
Power-law scaling
Power-law scaling
Landslide
Natural Hazard
Landslide-dammed lake
Cascading hazards
Landslide dam
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Summary:The size-frequency distributions of earth surface processes and landforms are often characterized by power-law scaling, indicating invariance over certain scale ranges. Determining such characteristic scaling improved the understanding and prediction of landslide occurrence. However, the scaling of lakes dammed by landslide deposits in rivers received much less attention, despite the effects on the river bed and the natural hazard potential resulting from dam breach. To escape data scarcity, we modeled eight million landslides and more than 50 thousand dammed lakes in eight mountain ranges around the world. We used an approach combining the determination of landslide release zones and volumes based on slope geometry and probability, the simulation of landslide runouts and the filling of depressions in the resulting land surface. The distributions of modeled landslides are in line with field observations and suggest climate as an important control on landsliding via the influence of fluvial and glacial imprint on relief and slope geometry. The size-frequency distributions of landslide-dammed lakes also follow a power-law scaling, but differ from the scaling of landslides. A clear dependence of lake distributions on climate cannot be determined. We attribute this to the role of cross-sectional and longitudinal valley shape facilitating the formation of large lakes also in fluvial mountains with moderate relief. •Landslide scaling differs for glacial and fluvial landscapes.•The size-frequency distributions of landslide-dammed lakes follow a power-law scaling.•Lake scaling exponents show a linear relationship to landslide exponents.•Simulation of landslide-dammed lake formation gives the most accurate risk assessment.
ISSN:0921-8181
1872-6364
DOI:10.1016/j.gloplacha.2023.104190