Classical solutions to the Boltzmann equations for gas mixture with unequal molecular masses

Abstract

The Boltzmann equation is essential for gas thermodynamics,as it models how the molecular density distribution F(t,x,v) changes over time. However, existing research primarily focuses on the single species Boltzmann equation, while investigations into gas mixtures with unequal molecular masses remain relatively limited. Notably, mixed gas studies have broader applications exemplified by Earth's atmosphere, composed of 78\% nitrogen, 21\% oxygen, and 1\% trace gases, where the N2 to O2 molecular mass ratio is 28:32 (simplified as 7:8). This work addresses the Boltzmann equations for such mixtures with unequal molecular masses (mA≠ mB), establishing the global in time existence of classical solutions near Maxwellians for soft potentials (-3<γ<0) in a periodic spatial domain. Our analysis encompasses arbitrary molecular mass ratios. Our analysis encompasses arbitrary molecular mass ratios. The main contribution of this paper lies in the detailed characterization of the linear collision operator's structure and establishing estimates for the nonlinear terms under unequal mass conditions. Consequently, these results may help advance spectral analysis for soft potentials as well as L2,L∞ frameworks in future studies of multi-component Boltzmann equations.