On Strong Convergence to Equilibrium for the Boltzmann Equation with Soft Potentials

Abstract

The paper concerns L1- convergence to equilibrium for weak solutions of the spatially homogeneous Boltzmann Equation for soft potentials (-4 <0), with and without angular cutoff. We prove the time-averaged L1-convergence to equilibrium for all weak solutions whose initial data have finite entropy and finite moments up to order greater than 2+||. For the usual L1-convergence we prove that the convergence rate can be controlled from below by the initial energy tails, and hence, for initial data with long energy tails, the convergence can be arbitrarily slow. We also show that under the integrable angular cutoff on the collision kernel with -1 <0, there are algebraic upper and lower bounds on the rate of L1-convergence to equilibrium. Our methods of proof are based on entropy inequalities and moment estimates.