Taylor dispersion and phase mixing in the non-cutoff Boltzmann equation on the whole space
Abstract
In this paper, we describe the long-time behavior of the non-cutoff Boltzmann equation with soft potentials near a global Maxwellian background on the whole space in the weakly collisional limit (i.e. infinite Knudsen number 1/ ∞). Specifically, we prove that for initial data sufficiently small (independent of the Knudsen number), the solution displays several dynamics caused by the phase mixing/dispersive effects of the transport operator v · ∇x and its interplay with the singular collision operator. For x-wavenumbers k with |k|, one sees an enhanced dissipation effect wherein the characteristic decay time-scale is accelerated to O(1/11+2s |k|2s1+2s), where s ∈ (0,1] is the singularity of the kernel (s=1 being the Landau collision operator, which is also included in our analysis); for |k| , one sees Taylor dispersion, wherein the decay is accelerated to O(/|k|2). Additionally, we prove almost-uniform phase mixing estimates. For macroscopic quantities as the density , these bounds imply almost-uniform-in- decay of (t∇x)β in L∞x due to Landau damping and dispersive decay.
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