An extension problem for the logarithmic Laplacian
Abstract
The logarithmic Laplacian on the (whole) N-dimensional Euclidean space is defined as the first variation of the fractional Laplacian of order 2s at s=0 or, alternatively, as a singular Fourier integral operator with logarithmic symbol. While this operator has attracted fastly growing attention in recent years due to its relevance in the study of order-dependent problems, a characterization via a local extension problem on the (N+1)-dimensional upper half-space in the spirit of the Cafferelli-Sivestre extension for the fractional Laplacian has been missing so far. In this paper, we establish such a characterization. More precisely, we show that, up to a multiplicative constant, the logarithmic Laplacian coincides with the boundary-value operator associated with a weighted second-order operator on the upper half-space, which maps inhomogeneous Neumann data to a Robin boundary-value of the corresponding distributional solution with a singular excess term. This extension property of the logarithmic Laplacian leads to a new energy functional associated with this operator. By doubling the extension-variable, we show that distributional solutions of the extension problem are actually harmonic in the (N+2)-dimensional Euclidean space away from the boundary. As an application of these results, we establish a weak unique continuation principle for the (stationary) logarithmic Laplace equation.
Cite
@article{arxiv.2312.15689,
title = {An extension problem for the logarithmic Laplacian},
author = {Huyuan Chen and Daniel Hauer and Tobias Weth},
journal= {arXiv preprint arXiv:2312.15689},
year = {2023}
}