Hydrodynamic limit of the Vlasov-Poisson-Boltzmann system for gas mixture

Abstract

In this paper, we study the hydrodynamic limit of the Vlasov-Poisson-Boltzmann system for a gas mixture in the whole space (x ∈ R3) with the potential range of γ ∈(-3, 1]. Using the method of Hilbert expansion, we first derive a bi-Maxwellian determined by the Euler-Poisson system of two fluids. To justify the convergence of the solution rigorously as the Knudsen number tends to zero, we sequentially calculate the first 2k-1 terms of the expansion series (k ≥ 6), and then truncate it, and express the solution as the sum of these first 2k-1 terms and a remainder term. Within the framework of the Lx,v2-Wx,v1,∞ interplay established by Guo and Jang [ininp]Guo2010CMP, we construct a new weight function to estimate the remainder term in four different cases regarding the potential γ. Here, the particle masses mA, mB > 0 and their charges eA, eB can be given arbitrarily. This causes the collision operator to exhibit asymmetric effects (mA ≠ mB), rendering the system of equations impossible to decouple. So, it adds difficulties to both L2, L∞ estimates for the remainder. Therefore, we adopt the framework of vector-valued functions and analyze the velocity decay rate of the operator KM,2,wα,c to eliminate the singularity induced by small parameters in characteristic line iterations. Our results show that the validity time of the solution is O(-y), where y is -2k-32(2k-1) when -1 ≤ γ ≤ 1, and it becomes -2k-3(1-γ)(2k-1), when -3 < γ < -1. These results possess strong physical realism and can be applied to analyze gas flow dynamics in the daytime ionosphere at high altitudes above the Earth.