H{\"o}rmander Functional Calculus for Poisson Estimates
Abstract
The aim of the article is to show a H{\"o}rmander spectral multiplier theorem for an operator whose kernel of the semigroup satisfies certain Poisson estimates for complex times Here acts on where is a space of homogeneous type with the additional condition that the measure of annuli is controlled. In most of the known H{\"o}rmander type theorems in the literature, Gaussian bounds and self-adjointness for the semigroup are needed, whereas here the new feature is that the assumptions are the to some extend weaker Poisson bounds, and calculus in place of self-adjointness. The order of derivation in our H{\"o}rmander multiplier result is typically being the dimension of the space Moreover the functional calculus resulting from our H{\"o}rmander theorem is shown to be -bounded. Finally, the result is applied to some examples.
Cite
@article{arxiv.1302.6104,
title = {H{\"o}rmander Functional Calculus for Poisson Estimates},
author = {Christoph Kriegler},
journal= {arXiv preprint arXiv:1302.6104},
year = {2018}
}
Comments
The manuscript has undergone several substantial improvements. The main result (Theorem 3.2 and Corollary 3.6) has weaker assumptions on the operator A: A is not assumed to be self-adjoint any more, but to have an H{\textdegree}{\textdegree} calculus on L^2 and that exp(-zA) admits a certain growth bound when z approaches the imaginary axis. The Lipschitz condition on the heat kernel is not needed any more. The space Omega is allowed to be of finite measure. On the other hand, the H{\"o}rmander calculus which is deduced has the optimal order d/2 in place of d/2 + 1 as before. Furthermore, 3 applications of the main result are given in Section 4. For 2 of them, the R-boundedness of the H{\"o}rmander calculus is new and for 1, the calculus itself is new and provides an example of H{\"o}rmander spectral multipliers on L^p for a non-seld-adjoint operator