3D Solver for Viscous Fluids to Simulate Lava Flows

Elisa Biagioli; Mattia De' Michieli Vitturi; Fabio Di Benedetto; Margherita Polacci

doi:10.51560/ofj.v5.128

3D Solver for Viscous Fluids to Simulate Lava Flows

Elisa Biagioli, Mattia De' Michieli Vitturi, Fabio Di Benedetto, Margherita Polacci

Earth and Environmental Sciences - Academic & Research

Research output: Contribution to journal › Article › peer-review

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Abstract

In this work, we present a new OpenFOAM solver, called interThermalRadConvFoam, to simulate free-surface viscous fluids with temperature changes due to radiative, convective, and conductive heat exchanges. The solver is based on interFoam (available in OpenFOAM) and thus on the Volume of Fluid technique used to describe the multiphase dynamics of two incompressible, viscous, and immiscible fluids (based on the Interface Capturing strategy). In our model, the two fluids are the fluid of interest with high viscosity and the surrounding atmosphere. Being interested in temperature effects, we added to the mass and momentum equations from interFoam an equation for energy that models the thermal exchanges between the fluid and the environment. Furthermore, a temperature-dependent viscoplastic model is used for the final application to lava flows. Here we present some results of numerical tests performed with interThermalRadConvFoam for a benchmark from literature based on a laboratory experiment and an application to a real lava flow by simulating the Pico do Fogo 2014–2015 Eruption. For the simulation of the laboratory experiment, we also present simulations executed using a dynamic mesh with adaptive refinement.

Original language	English
Pages (from-to)	90-114
Journal	OpenFOAM® Journal
Volume	5
DOIs	https://doi.org/10.51560/ofj.v5.128
Publication status	Published - 23 Apr 2025

Keywords

3D multiphase lava flow model
Heat transfer modelling
Temperature-dependent non Arrhenian Newtonian visciosity
Flow on a real topography

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10.51560/ofj.v5.128Licence: CC BY-SA

Biagioli_etal_2025_openFoamFinal published version, 7.98 MBLicence: CC BY-SA

Petrology and volcanology
Burton, M. (PI), Hartley, M. (PI), Mccormick Kilbride, B. (PI), Mitchell, N. (PI), Neave, D. (PI), Pawley, A. (PI), Polacci, M. (PI), Biagioli, E. (Researcher), Bonechi, B. (Researcher), Buso, R. (Researcher), Davies, B. (Researcher), Esse, B. (Researcher), Bronziet, J. (PGR student), Delbrel, J. (PGR student), Höhn, M. (PGR student), Kember, A. (PGR student), Pardo Cofrades, A. (PGR student), Sen, R. (PGR student), Stewart, A. (PGR student) & Subbaraman, R. (PGR student)
Project: Research

Cite this

@article{fcb427df4da14e69a1c8e15836dc946b,

title = "3D Solver for Viscous Fluids to Simulate Lava Flows",

abstract = "In this work, we present a new OpenFOAM solver, called interThermalRadConvFoam, to simulate free-surface viscous fluids with temperature changes due to radiative, convective, and conductive heat exchanges. The solver is based on interFoam (available in OpenFOAM) and thus on the Volume of Fluid technique used to describe the multiphase dynamics of two incompressible, viscous, and immiscible fluids (based on the Interface Capturing strategy). In our model, the two fluids are the fluid of interest with high viscosity and the surrounding atmosphere. Being interested in temperature effects, we added to the mass and momentum equations from interFoam an equation for energy that models the thermal exchanges between the fluid and the environment. Furthermore, a temperature-dependent viscoplastic model is used for the final application to lava flows. Here we present some results of numerical tests performed with interThermalRadConvFoam for a benchmark from literature based on a laboratory experiment and an application to a real lava flow by simulating the Pico do Fogo 2014–2015 Eruption. For the simulation of the laboratory experiment, we also present simulations executed using a dynamic mesh with adaptive refinement.",

keywords = "3D multiphase lava flow model, Heat transfer modelling, Temperature-dependent non Arrhenian Newtonian visciosity, Flow on a real topography",

author = "Elisa Biagioli and \{De' Michieli Vitturi\}, Mattia and \{Di Benedetto\}, Fabio and Margherita Polacci",

year = "2025",

month = apr,

day = "23",

doi = "10.51560/ofj.v5.128",

language = "English",

volume = "5",

pages = "90--114",

journal = "OpenFOAM{\textregistered} Journal",

issn = "2753-8168",

publisher = "OpenCFD Ltd",

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TY - JOUR

T1 - 3D Solver for Viscous Fluids to Simulate Lava Flows

AU - Biagioli, Elisa

AU - De' Michieli Vitturi, Mattia

AU - Di Benedetto, Fabio

AU - Polacci, Margherita

PY - 2025/4/23

Y1 - 2025/4/23

N2 - In this work, we present a new OpenFOAM solver, called interThermalRadConvFoam, to simulate free-surface viscous fluids with temperature changes due to radiative, convective, and conductive heat exchanges. The solver is based on interFoam (available in OpenFOAM) and thus on the Volume of Fluid technique used to describe the multiphase dynamics of two incompressible, viscous, and immiscible fluids (based on the Interface Capturing strategy). In our model, the two fluids are the fluid of interest with high viscosity and the surrounding atmosphere. Being interested in temperature effects, we added to the mass and momentum equations from interFoam an equation for energy that models the thermal exchanges between the fluid and the environment. Furthermore, a temperature-dependent viscoplastic model is used for the final application to lava flows. Here we present some results of numerical tests performed with interThermalRadConvFoam for a benchmark from literature based on a laboratory experiment and an application to a real lava flow by simulating the Pico do Fogo 2014–2015 Eruption. For the simulation of the laboratory experiment, we also present simulations executed using a dynamic mesh with adaptive refinement.

AB - In this work, we present a new OpenFOAM solver, called interThermalRadConvFoam, to simulate free-surface viscous fluids with temperature changes due to radiative, convective, and conductive heat exchanges. The solver is based on interFoam (available in OpenFOAM) and thus on the Volume of Fluid technique used to describe the multiphase dynamics of two incompressible, viscous, and immiscible fluids (based on the Interface Capturing strategy). In our model, the two fluids are the fluid of interest with high viscosity and the surrounding atmosphere. Being interested in temperature effects, we added to the mass and momentum equations from interFoam an equation for energy that models the thermal exchanges between the fluid and the environment. Furthermore, a temperature-dependent viscoplastic model is used for the final application to lava flows. Here we present some results of numerical tests performed with interThermalRadConvFoam for a benchmark from literature based on a laboratory experiment and an application to a real lava flow by simulating the Pico do Fogo 2014–2015 Eruption. For the simulation of the laboratory experiment, we also present simulations executed using a dynamic mesh with adaptive refinement.

KW - 3D multiphase lava flow model

KW - Heat transfer modelling

KW - Temperature-dependent non Arrhenian Newtonian visciosity

KW - Flow on a real topography

U2 - 10.51560/ofj.v5.128

DO - 10.51560/ofj.v5.128

M3 - Article

SN - 2753-8168

VL - 5

SP - 90

EP - 114

JO - OpenFOAM® Journal

JF - OpenFOAM® Journal

ER -

3D Solver for Viscous Fluids to Simulate Lava Flows

Abstract

Keywords

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Projects

Petrology and volcanology

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