The Neumann problem for the fractional Laplacian: optimal regularity via the Mellin transform
Abstract
We establish the optimal regularity of solutions to the Neumann problem for the fractional Laplacian, (-)s u=h in , with the external condition Ns u=0 in c. For this, a key point is to establish a 1D Liouville theorem for functions with growth, which we prove by using complex analysis and the Mellin transform. More precisely, we prove a ``meta-theorem'' relating the classification of 1D solutions to general linear homogeneous equations of the type Lu=0 in (0,∞) to the (complex) roots of an explicit meromorphic function f(z) that depends on L. In case of the fractional Laplacian with Neumann conditions, we show that all solutions are C2s+α when s≤ 1/2, and Cs+12+α when s≥1/2. Moreover, quite surprisingly, we prove that even in 1D there exist highly oscillating solutions of the type u(x)=xa (b x) for x>0, with a>0 and b>0 that depend on s, and a<2s for s1.
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