IMEX_SfloW2D 1.0: a depth-averaged numerical flow model for pyroclastic avalanches
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Published:2019-02-01
Issue:1
Volume:12
Page:581-595
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ISSN:1991-9603
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Container-title:Geoscientific Model Development
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language:en
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Short-container-title:Geosci. Model Dev.
Author:
de' Michieli Vitturi MattiaORCID, Esposti Ongaro TomasoORCID, Lari Giacomo, Aravena Alvaro
Abstract
Abstract. Pyroclastic avalanches are a type of granular flow generated at active
volcanoes by different mechanisms, including the collapse of steep
pyroclastic deposits (e.g., scoria and ash cones), fountaining during
moderately explosive eruptions, and crumbling and gravitational collapse of
lava domes. They represent end-members of gravity-driven pyroclastic flows
characterized by relatively small volumes (less than about 1 Mm3) and
relatively thin (1–10 m) layers at high particle concentration
(10–50 vol %), manifesting strong topographic control. The simulation of
their dynamics and mapping of their hazards pose several different problems
to researchers and practitioners, mostly due to the complex and still poorly
understood rheology of the polydisperse granular mixture and to the
interaction with the complex natural three-dimensional topography, which
often causes rapid rheological changes. In this paper, we present
IMEX_SfloW2D, a depth-averaged flow model describing the granular mixture as
a single-phase granular fluid. The model is formulated in absolute Cartesian
coordinates (whereby the fluid flow equations are integrated along the
direction of gravity) and can be solved over a topography described by a
digital elevation model. The numerical discretization and solution algorithms
are formulated to allow for a robust description of wet–dry conditions (thus
allowing us to accurately track the front propagation) and an implicit
solution to
the nonlinear friction terms. Owing to these features, the model is able to
reproduce steady solutions, such as the triggering and stopping phases of the
flow, without the need for empirical conditions. Benchmark cases are discussed
to verify the numerical code implementation and to demonstrate the main
features of the new model. A preliminary application to the simulation of the
11 February pyroclastic avalanche at the Etna volcano (Italy) is finally
presented. In the present formulation, a simple semi-empirical friction model
(Voellmy–Salm rheology) is implemented. However, the modular structure of the
code facilitates the implementation of more specific and calibrated
rheological models for pyroclastic avalanches.
Publisher
Copernicus GmbH
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