Invariant density & time asymptotics for collisionless kinetic equations with partly diffuse boundary operators

Abstract: This paper deals with collisionless transport equations in bounded open domains $\Omega \subset \R^{d}$ $(d\geq 2)$ with $\mathcal{C}^{1}$ boundary $\partial \Omega $, orthogonally invariant velocity measure $\bm{m}(\d v)$ with support $V\subset \R^{d}$ and stochastic partly diffuse boundary operators $\mathsf{H}$ relating the outgoing and incoming fluxes. Under very general conditions, such equations are governed by stochastic $C_{0}$-semigroups $\left( U_{\mathsf{H}}(t)\right) {t\geq 0}$ on $% L^{1}(\Omega \times V,\d x \otimes \bm{m}(\d v)).$ We give a general criterion of irreducibility of $% \left( U{\mathsf{H}}(t)\right) {t\geq 0}$ and we show that, under very natural assumptions, if an invariant density exists then $\left( U{\mathsf{H}}(t)\right) {t\geq 0}$ converges strongly (not simply in Cesar`o means) to its ergodic projection. We show also that if no invariant density exists then $\left( U{\mathsf{H}}(t)\right) {t\geq 0}$ is \emph{sweeping} in the sense that, for any density $\varphi $, the total mass of $ U{\mathsf{H}}(t)\varphi $ concentrates near suitable sets of zero measure as $ t\rightarrow +\infty .$ We show also a general weak compactness theorem of interest for the existence of invariant densities. This theorem is based on several results on smoothness and transversality of the dynamical flow associated to $\left( U_{\mathsf{H}}(t)\right) _{t\geq 0}.$