Violent Relaxation, Phase Mixing, and Gravitational Landau Damping

Abstract

This paper proposes a geometric interpretation of flows generated by the collisionless Boltzmann equation (CBE), focusing on the coarse-grained approach towards equilibrium. The CBE is a noncanonical Hamiltonian system with the distribution function f the fundamental dynamical variable, the mean field energy H[f] playing the role of the Hamiltonian and the natural arena of physics being the infinite-dimensional phase space of distribution functions. Every time-independent equilibrium f_0 is an energy extremal with respect to all perturbations that preserve the constraints associated with Liouville's Theorem, local energy minima corresponding to linearly stable equilibria. If an initial f(t=0) is sufficiently close to some linearly stable lower energy f_0, its evolution involves linear phase space oscillations about f_0 which, in many cases, would be expected to exhibit linear Landau damping. If f(t=0) is far from any stable extremal, the flow will be more complicated but, in general, one would anticipate that the evolution involves nonlinear oscillations about some lower energy f_0. In this picture, the coarse-grained approach towards equilibrium usually termed violent relaxation is interpreted as nonlinear Landau damping. The evolution of a generic initial f(t=0) involves a coherent initial excitation, not necessarily small, being converted into incoherent motion associated with nonlinear oscillations about some equilibrium f_0 which, in general, will exhibit destructive interference.