Kinetic theory based force treatment in lattice Boltzmann equation

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)(,u, T) with an external force term, where the fluid density, 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 fi apparently relaxed to a given state f(eq)i(,u*), where the given velocity u* could be different with u, and the Chapman-Enskog analysis showed that f(0)i and local equilibrium density distribution function should be f(eq)i(,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(,u) with fi relaxed to f(eq)i(,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.