The structure of solution spaces for fractional-order operators, with gradient estimates
Abstract
The solution space of the homogeneous Dirichlet problem for the fractional Laplacian (-Δ)a (0<a<1) or a pseudodifferential generalization P, on a bounded open set Ω⊂ Rn with C1+τ-boundary, Pu=f on Ω, u=0 on Rn Ω, is analysed in detail. It is shown, both for solutions in Sobolev spaces of Bessel-potential type Hqt and in Hölder-Zygmund spaces C*t, that the solution space for f of regularity s∈ [0,τ-2a) is the direct sum of a component Hq2a+s(Ω) resp. C*2a+s(Ω) with full regularity 2a+s and a component of the form da times a lifting of boundary values by Poisson operators. Here d(x)=dist(x,∂Ω). This extends to non-smooth problems results known in the C∞ setting. The knowledge is used to establish gradient estimates for a>1/2, e.g. estimating d1-a+s∇ (u/da) in terms of norms of f and u, both in Hqt-spaces and C*t-spaces. This is entirely new in the case of Bessel-potential spaces; it extends previous results by Fall and Jarohs in Hölder spaces. A new tool is introduced: Hs+tq(Ω)⊂ ds Htq(Ω) holds for s,t 0 with s+t<1+τ.
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