The Boltzmann equation in the homogeneous critical regularity framework

Abstract

We construct a unique global solution to the Cauchy problem of the 3D Boltzmann equation for initial data around the Maxwellian in the spatially critical homogeneous Besov space L2(B2,11/2B2,13/2). In addition, under the condition that the low-frequency part of initial perturbation is bounded in L2(B2,∞σ0) with -3/2≤σ0<1/2, it is shown that the solution converges to its equilibrium in large times with the optimal rate of O(t-(σ-σ0)/2) in L2(B2,1σ) with some σ>σ0, and the microscopic part decays at an enhanced rate of O(t-(σ-σ0)/2-1/2). In contrast to [19], the usual L2 estimates are not necessary in our approach, which provides a new understanding of hypocoercivity theory for the Boltzmann equation allowing to construct the Lyapunov functional with different dissipation rates at low and high frequencies. Furthermore, a time-weighted Lyapunov energy argument can be developed to deduce the optimal time-decay estimates.