A lattice Boltzmann model for reactive mixtures

A new lattice Boltzmann model for reactive ideal gas mixtures is presented. The model is an extension to reactive flows of the recently proposed multi-component lattice Boltzmann model for compressible ideal gas mixtures with Stefan-Maxwell diffusion for species interaction. First, the kinetic model for the Stefan-Maxwell diffusion is enhanced to accommodate a source term accounting for the change in the mixture composition due to chemical reaction. Second, by including the heat of formation in the energy equation, the thermodynamic consistency of the underlying compressible lattice Boltzmann model for momentum and energy allows a realization of the energy and temperature change due to chemical reactions. This obviates the need for ad-hoc modelling with source terms for temperature or heat. Both parts remain consistently coupled through mixture composition, momentum, pressure, energy and enthalpy. The proposed model uses the standard three-dimensional lattices and is validated with a set of benchmarks including laminar burning speed in the hydrogen-air mixture and circular expanding premixed flame. This article is part of the theme issue 'Progress in mesoscale methods for fluid dynamics simulation'.

Automated summary

A new lattice Boltzmann model for reactive ideal gas mixtures is proposed, which improves the kinetic model for Stefan-Maxwell diffusion and enhances thermodynamic consistency by incorporating the heat of formation to accurately describe the energy and temperature changes due to chemical reactions. The model is validated with benchmarks including laminar burning speed in hydrogen-air mixture and circular expanding premixed flame, demonstrating its effectiveness for reactive flows.