Probabilistic description of dissipative chaotic scattering

TL;DR

This paper analyzes how dissipation affects chaotic scattering systems, showing that for small dissipation and long times, the system's behavior can be predicted from the dissipation-free case, with results validated in the Henon-Heiles model.

Contribution

It introduces a theoretical framework linking dissipative chaotic scattering properties to the dissipation-free system, including effective escape rates and trajectory distributions.

Findings

Exponential decay of survival probability at large energies

Different finite-time regimes emerge due to dissipation

Numerical validation in the Henon-Heiles model

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 $P(t) \sim e^{-\kappa t}$ with an escape rate $\kappa$ that decreases with $E$. Dissipation $\gamma>0$ leads to the appearance of different finite-time regimes in $P(t)$. We show how these different regimes can be understood for small $\gamma\ll 1$ and $t\gg 1/\kappa_0$ from the effective escape rate $\kappa_\gamma(t)=\kappa_0(E(t))$ (including the non-hyperbolic regime) until the energy reaches a critical value $E_c$ at which no escape is possible. More generally, we argue that for small dissipation $\gamma$ 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.