Essential normality, essential norms and hyperrigidity
Abstract
Let denote the compression of the -shift to the complement of a homogeneous ideal of . Arveson conjectured that is essentially normal. In this paper, we establish new results supporting this conjecture, and connect the notion of essential normality to the theory of the C*-envelope and the noncommutative Choquet boundary. The unital norm closed algebra generated by modulo the compact operators is shown to be completely isometrically isomorphic to the uniform algebra generated by polynomials on , where is the variety corresponding to . Consequently, the essential norm of an element in is equal to the sup norm of its Gelfand transform, and the C*-envelope of is identified as the algebra of continuous functions on , which means it is a complete invariant of the topology of the variety determined by in the ball. Motivated by this determination of the C*-envelope of , we suggest a new, more qualitative approach to the problem of essential normality. We prove the tuple is essentially normal if and only if it is hyperrigid as the generating set of a C*-algebra, which is a property closely connected to Arveson's notion of a boundary representation. We show that most of our results hold in a much more general setting. In particular, for most of our results, the ideal can be replaced by an arbitrary (not necessarily homogeneous) invariant subspace of the -shift.
Keywords
Cite
@article{arxiv.1309.3737,
title = {Essential normality, essential norms and hyperrigidity},
author = {Matthew Kennedy and Orr Shalit},
journal= {arXiv preprint arXiv:1309.3737},
year = {2015}
}
Comments
28 pages