On a generalized maximum principle for a transport-diffusion model with -modulated fractional dissipation

Abstract

We consider a transport-diffusion equation of the form ∂t θ +v · ∇ θ + θ =0, where v is a given time-dependent vector field on Rd. The operator represents log-modulated fractional dissipation: = |∇|γβ(λ+|∇|) and the parameters 0, β 0, 0 γ 2, λ>1. We introduce a novel nonlocal decomposition of the operator in terms of a weighted integral of the usual fractional operators |∇|s, 0 s γ plus a smooth remainder term which corresponds to an L1 kernel. For a general vector field v (possibly non-divergence-free) we prove a generalized L∞ maximum principle of the form |θ(t)|∞ eCt |θ0|∞ where the constant C=C(,β,γ)>0. In the case div(v)=0 the same inequality holds for |θ(t)|p with 1 p ∞. At the cost of an exponential factor, this extends a recent result of Hmidi (2011) to the full regime d 1, 0 γ 2 and removes the incompressibility assumption in the L∞ case.