Equilibration in the Kac Model using the GTW Metric d2

Abstract

We use the Fourier based Gabetta-Toscani-Wennberg (GTW) metric d2 to study the rate of convergence to equilibrium for the Kac model in 1 dimension. We take the initial velocity distribution of the particles to be a Borel probability measure μ on Rn that is symmetric in all its variables, has mean 0 and finite second moment. Let μt(dv) denote the Kac-evolved distribution at time t, and let Rμ be the angular average of μ. We give an upper bound to d2(μt, Rμ) of the form \ B e-4 λ1n+3t, d2(μ,Rμ)\, where λ1 = n+22(n-1) is the gap of the Kac model in L2 and B depends only on the second moment of μ. We also construct a family of Schwartz probability densities \f0(n): Rn→ R\ with finite second moments that shows practically no decrease in d2(f0(t), Rf0) for time at least 12λ with λ the rate of the Kac operator. We also present a propagation of chaos result for the partially thermostated Kac model in [14].