Probabilistic description of dissipative chaotic scattering

Abstract

We investigate the extent to which the probabilistic properties of a chaotic scattering system with dissipation can be understood from the properties of the dissipation-free system. For large energies E, a fully chaotic scattering leads to an exponential decay of the survival probability P(t) e- t with an escape rate that decreases with E. Dissipation γ>0 leads to the appearance of different finite-time regimes in P(t). We show how these different regimes can be understood for small γ 1 and t 1/0 from the effective escape rate γ(t)=0(E(t)) (including the non-hyperbolic regime) until the energy reaches a critical value Ec at which no escape is possible. More generally, we argue that for small dissipation γ and long times t the surviving trajectories in the dissipative system are distributed according to the conditionally invariant measure of the conservative system at the corresponding energy E(t)<E(0). Quantitative predictions of our general theory are compared with numerical simulations in the Henon-Heiles model.