Fractional Besov-Sobolev Spaces on Quasicircles

Abstract

Let be a bounded Jordan curve and i,e its two complementary components. For p∈ (1, ∞),\,s∈(0,1) we define the two spaces Bp,ps(i,e) as the set of harmonic functions u respectively in i and e such that _i,e |∇ u(z)|p d(z,)(1-s)p-1 dxdy<+∞. When it is possible to identify these spaces with spaces of functions on the boundary (trace spaces), we address the question of their equality. When is the unit circle, these two spaces coincide with homogeneous fractional Besov-Sobolev spaces and the framework of quasicircles appears to be an appropriate generalization. In this framework, we study the boundedness of the Plemelj-Calder\'on operator and apply the results to show that for some values of p,s, if the two spaces coincide, they are restrictions to of some weighted Sobolev space. If is further assumed to be rectifiable, we define Bp,ps() as the space of functions f∈ Lp() such that × |f(z)-f(ζ)|p|z-ζ|1+ps |dz||dζ|<+∞. Again, these spaces coincide with the homogeneous fractional Besov-Sobolev spaces for the unit circle. While the chord-arc property is the necessary and sufficient condition for the equality Bp,ps(i)=Bp,ps(e)=Bp,ps() in the case of s=1/p,\, p 2, this is no longer the case for general s∈ (0,1). However, we show that equality holds for radial-Lipschitz curves. Finally, we re-interpretate some of our results as some "almost"-Dirichlet principle in the spirit of Maz'ya.