Extensions of divergence-free fields in L1-based function spaces

Abstract

We establish the first extension results for divergence-free (or solenoidal) elements of L1-based function spaces. Here, the key point is to preserve the solenoidality constraint while simultaneously keeping the underlying L1-boundedness. While previous results as in Kato et al. [Extension and representation of divergence-free vector fields on bounded domains, Math. Res. Lett., 2000] for Lp-based function spaces, 1<p<∞, rely on PDE approaches, basic principles from harmonic analysis rule out such strategies in the L1-context. By means of a novel method adapted to the divergence-free constraint via differential forms, we establish the existence of such extension operators in the L1-based situation. This applies both to the case of convex domains, where a global extensions can be achieved, as well as to the Lipschitz case, where a local extension can be achieved. Being applicable to 1<p<∞ too, our method provides a unifying approach to the cases p∈\1,∞\ and 1<p<∞. Specifically, covering the exponents p∈\1,∞\, this answers a borderline case left open by Kato et al. [Extension and representation of divergence-free vector fields on bounded domains, Math. Res. Lett., 2000] in the affirmative. By use of explicit examples, the assumptions on the underlying domains are shown to be almost optimal.