Computational experiments on the 1962 and 1970 landslide events at Huascaran (Peru) with r.avaflow

Autor(en)

Martin Mergili, Bernhard Frank, Jan-Thomas Fischer, Christian Huggel, Shiva Prasad Pudasaini

Abstrakt

Mass flow simulations are considered important tools for hazard analysis. For the simulation of single process mass flows such as debris flows, robust tools and reasonable parameter range estimates are available. However, this is much less the case for more complex mass flows, e.g. involving process chains and flow transformation. We explore the challenges of simulating complex flow-dominated landslides by back-calculating the Huascarán events of 1962 and 1970 with r.avaflow, a two-phase mass flow model (Pudasaini, 2012) in a GIS-based open source simulation framework. Both events started as rock-ice falls on the western slope of the north summit of Nevado Huascarán (Cordillera Blanca, Peru) and entrained large volumes of glacial till at lower elevation, resulting in highly mobile debris avalanches. Whereas the 1962 event badly affected the village of Ranrahirca when spreading over a debris cone, the 1970 event overtopped a ridge and led to the complete destruction of the town of Yungay. Well documented in the literature, these events provide an opportunity as a natural laboratory for testing innovative mass flow simulation tools and their features. In a first step, we consider (i) the 1962 event and (ii) the 1970 event separately, for each of them optimizing the key input parameters in terms of empirical adequacy. In a second step, we apply the optimized parameter set for (i) to the 1970 event and the parameter set derived for (ii) to the 1962 event. In a third step, we explore the sensitivity of the model outcomes to selected key parameters (basal friction angle and entrainment coefficient). The results (a) demonstrate the general ability of r.avaflow to reproduce the spatio-temporal evolution of flow heights and velocities as well as travel times and volumes of these complex mass flow events reasonably well; and (b) highlight the challenges and uncertainties involved in predictive simulations with parameter sets obtained from back-calculations. We suggest a strategy to appropriately deal with uncertain outcomes by superimposing the results of multiple simulations.

Organisation(en)

Institut für Geographie und Regionalforschung

Externe Organisation(en)

Bundesforschungs- und Ausbildungszentrum für Wald, Naturgefahren und Landschaft (BFW), Universität Zürich (UZH), Rheinische Friedrich-Wilhelms-Universität Bonn, Universität für Bodenkultur Wien

Journal

Geomorphology

Band

322

Seiten

15-28

Anzahl der Seiten

14

ISSN

0169-555X

DOI

https://doi.org/10.1016/j.geomorph.2018.08.032

Publikationsdatum

12-2018

Peer-reviewed

Ja

ÖFOS 2012

107007 Risikoforschung, 207206 Ingenieurgeologie, 105408 Physische Geographie, 102009 Computersimulation

Schlagwörter

ASJC Scopus Sachgebiete

Earth-Surface Processes

Link zum Portal

https://ucrisportal.univie.ac.at/de/publications/f776d2ee-6124-4b91-a01b-9c10ff0b99ae