Litcius/Paper detail

A Multi-Fidelity Framework for Wildland Fire Behavior Simulations over Complex Terrain

Marcos Vanella, Kevin B. McGrattan, Randall McDermott, Glenn P. Forney, William Mell, Emanuele Gissi, Paolo Fiorucci

2021Atmosphere38 citationsDOIOpen Access PDF

Abstract

A method for the large-eddy simulation (LES) of wildfire spread over complex terrain is presented. In this scheme, a cut-cell immersed boundary method (CC-IBM) is used to render the complex terrain, defined by a tessellation, on a rectilinear Cartesian grid. Discretization of scalar transport equations for chemical species is done via a finite volume scheme on cut-cells defined by the intersection of the terrain geometry and the Cartesian cells. Momentum transport and heat transfer close to the immersed terrain are handled using dynamic wall models and a direct forcing immersed boundary method. A new “open” convective inflow/outflow method for specifying atmospheric wind boundary conditions is presented. Additionally, three basic approaches have been explored to model fire spread: (1) Representing the vegetation as a collection of Lagrangian particles, (2) representing the vegetation as a semi-porous boundary, and (3) representing the fire spread using a level set method, in which the fire spreads as a function of terrain slope, vegetation type, and wind speed. Several test and validation cases are reported to demonstrate the capabilities of this novel wildfire simulation methodology.

Topics & Concepts

TerrainImmersed boundary methodInflowBoundary (topology)DiscretizationMeteorologyFinite volume methodCartesian coordinate systemEnvironmental scienceGeologyComputer scienceGeometryMechanicsMathematicsPhysicsGeographyMathematical analysisCartographyFire effects on ecosystemsLattice Boltzmann Simulation StudiesPlant Water Relations and Carbon Dynamics