IMEX_SfloW2D v2: a depth-averaged numerical flow model for volcanic gas–particle flows over complex topographies and water

We present developments to the physical model and the open-source numerical code IMEX_SfloW2D (de' Michieli Vitturi et al., 2019). These developments consist of a generalization of the depth-averaged (shallow-water) fluid equations to describe a polydisperse fluid–solid mixture, including terms...

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Bibliographic Details
Published in:Geoscientific Model Development 2023-11, Vol.16 (21), p.6309-6336
Main Authors: de' Michieli Vitturi, Mattia, Esposti Ongaro, Tomaso, Engwell, Samantha
Format: Article
Language:English
Subjects:
Algorithms
Approximation
Avalanches
Benchmarks
Boundary conditions
Density currents
Entrainment
Equilibrium flow
Fluid flow
Landslides
Lava
Mass flow
Mathematical models
Modelling
Numerical analysis
Partial differential equations
Propagation
Robustness (mathematics)
Sea surface
Sedimentation & deposition
Shallow water
Simulation
Software quality
Source code
Topography
Transcritical flow
Transport equations
Two dimensional flow
Vaporization
Velocity
Volcanic activity
Volcanic gases
Volcanoes
Water depth
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Summary:We present developments to the physical model and the open-source numerical code IMEX_SfloW2D (de' Michieli Vitturi et al., 2019). These developments consist of a generalization of the depth-averaged (shallow-water) fluid equations to describe a polydisperse fluid–solid mixture, including terms for sedimentation and entrainment, transport equations for solid particles of different sizes, transport equations for different components of the carrier phase, and an equation for temperature/energy. Of relevance for the simulation of volcanic mass flows, vaporization and entrainment of water are implemented in the new model. The model can be easily adapted to simulate a wide range of volcanic mass flows (pyroclastic avalanches, lahars, pyroclastic surges), and here we present its application to transient dilute pyroclastic density currents (PDCs). The numerical algorithm and the code have been improved to allow for simulation of sub- to supercritical regimes and to simplify the setting of initial and boundary conditions. The code is open-source. The results of synthetic numerical benchmarks demonstrate the robustness of the numerical code in simulating transcritical flows interacting with the topography. Moreover, they highlight the importance of simulating transient in comparison to steady-state flows and flows in 2D versus 1D. Finally, we demonstrate the model capabilities to simulate a complex natural case involving the propagation of PDCs over the sea surface and across topographic obstacles, through application to Krakatau volcano, showing the relevance, at a large scale, of non-linear fluid dynamic features, such as hydraulic jumps and von Kármán vortices, to flow conditions such as velocity and runout.
ISSN:1991-9603
1991-959X
1991-962X
1991-9603
1991-962X
DOI:10.5194/gmd-16-6309-2023