Kinetic theory based force treatment in lattice Boltzmann equation

TL;DR

This paper derives a force treatment for the lattice Boltzmann equation based on kinetic theory, ensuring consistency with the Maxwellian distribution and accurately recovering Navier-Stokes equations.

Contribution

It establishes a force treatment in LBE grounded in kinetic theory, clarifying the distribution functions and improving the accuracy of hydrodynamic simulations.

Findings

The Maxwellian distribution $f^{(eq)}_i( ho,\textbf{u})$ should be used for local equilibrium.

The force term requirements are derived to recover Navier-Stokes equations.

Numerical results validate the theoretical analysis.

Abstract

In the gas kinetic theory, it showed that the zeroth order of the density distribution function $f^{(0)}$ and local equilibrium density distribution function were the Maxwellian distribution $f^{(eq)}(\rho,\emph{\textbf{u}}, T)$ with an external force term, where $\rho$ the fluid density, $\emph{\textbf{u}}$ the physical velocity and $T$ the temperature, while in the lattice Boltzmann equation (LBE) method numerous force treatments were proposed with a discrete density distribution function $f_i$ apparently relaxed to a given state $f^{(eq)}_i(\rho,\emph{\textbf{u}}^*)$, where the given velocity $\emph{\textbf{u}}^*$ could be different with $\emph{\textbf{u}}$, and the Chapman-Enskog analysis showed that $f^{(0)}_i$ and local equilibrium density distribution function should be $f^{(eq)}_i(\rho,\emph{\textbf{u}}^*)$ in the literature. In this paper, we start from the kinetic theory and show that the $f^{(0)}_i$ and local equilibrium density distribution function in LBE should obey the Maxwellian distribution $f^{(eq)}_i(\rho,\emph{\textbf{u}})$ with $f_i$ relaxed to $f^{(eq)}_i(\rho,\emph{\textbf{u}}^*)$, which are consistent with kinetic theory, then the general requirements for the force term are derived, by which the correct hydrodynamic equations could be recovered at Navier-Stokes level, and numerical results confirm our theoretical analysis.