Phase mixing and the Vlasov equation in cosmology
Abstract
We consider the Vlasov equation on slowly expanding isotropic homogeneous tori, described by the Friedmann--Lema\itre--Robertson--Walker cosmological spacetimes. For expansion rate tq, with 0< q<12 (excluding certain exceptional values), we show that the spatial density decays at the rate t-6q and that, when the spatial average is removed, the density decays at an enhanced rate due to a phase mixing effect. This enhancement is polynomial for Sobolev initial data and super-polynomial, but sub-exponential, for real analytic initial data. We further show that, when the expansion rate is the borderline t12 -- the rate which describes a radiation filled universe -- a degenerate phase mixing effect results in a logarithmic enhancement for Sobolev initial data and a super-logarithmic enhancement (in fact, a gain of (-μ( t)ε) for some μ,ε>0) for analytic initial data. The proof is based on a collection of commuting vector fields, and certain combinatorial properties of an associated collection of differential operators. The vector fields are not explicit, but are shown to have good properties when t is large with respect to the momentum support of the solution. A physical space dyadic localisation is employed to treat non-compactly supported (in particular, non-trivial real analytic) but suitably decaying solutions.
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