Operator theory on generalized Hartogs triangles
Abstract
We consider the family of -tuples consisting of polynomials with nonnegative coefficients which satisfy With any such we associate a Reinhardt domain that we will call the generalized Hartogs triangle. We are particularly interested in the choices where The generalized Hartogs triangle associated with is given by \begin{equation} \triangle^{\!n}_a = \Big\{z \in \mathbb C \times \mathbb C^{n-1}_* : |z_j|^2 < |z_{j+1}|^2(1-a|z_1|^2), ~j=1, \ldots, n-1, |z_n|^2 + a|z_1|^2 < 1\Big\}. \end{equation} The domain is never polynomially convex. However, is always holomorphically convex. With any and we associate a positive semi-definite kernel on This combined with the Moore's theorem yields a reproducing kernel Hilbert space of holomorphic functions on We study the space and the multiplication -tuple acting on It turns out that is never rationally cyclic. Although the dimension of the joint kernel of is constant of value for every , it has jump discontinuity at the serious singularity of the boundary of with value equal to We capitalize on the notion of joint subnormality to define a Hardy space on This in turn gives an analog of the von Neumann's inequality for
Cite
@article{arxiv.2210.05971,
title = {Operator theory on generalized Hartogs triangles},
author = {Sameer Chavan and Shubham Jain and Paramita Pramanick},
journal= {arXiv preprint arXiv:2210.05971},
year = {2022}
}
Comments
Revised version with a figure; 42 pages