On semi-classical limit of spatially homogeneous quantum Boltzmann equation: asymptotic expansion

Abstract

We continue our previous work [Ling-Bing He, Xuguang Lu and Mario Pulvirenti, Comm. Math. Phys., 386(2021), no. 1, 143223.] on the limit of the spatially homogeneous quantum Boltzmann equation as the Planck constant ε tends to zero, also known as the semi-classical limit. For general interaction potential, we prove the following: (i). The spatially homogeneous quantum Boltzmann equations are locally well-posed in some weighted Sobolev spaces with quantitative estimates uniformly in ε. (ii). The semi-classical limit can be further described by the following asymptotic expansion formula: fε(t,v)=fL(t,v)+O(ε). This holds locally in time in Sobolev spaces. Here fε and fL are solutions to the quantum Boltzmann equation and the Fokker-Planck-Landau equation with the same initial data.The convergent rate 0< ≤ 1 depends on the integrability of the Fourier transform of the particle interaction potential. Our new ingredients lie in a detailed analysis of the Uehling-Uhlenbeck operator from both angular cutoff and non-cutoff perspectives.