English

Operator algebras for analytic varieties

Operator Algebras 2015-03-20 v5

Abstract

We study the isomorphism problem for the multiplier algebras of irreducible complete Pick kernels. These are precisely the restrictions MV\mathcal M_V of the multiplier algebra M\mathcal M of Drury-Arveson space to a holomorphic subvariety VV of the unit ball Bd\mathbb{B}_d. We find that MV\mathcal M_V is completely isometrically isomorphic to MW\mathcal M_W if and only if WW is the image of VV under a biholomorphic automorphism of the ball. In this case, the isomorphism is unitarily implemented. This is then strengthend to show that, when d<d<\infty, every isometric isomorphism is completely isometric. The problem of characterizing when two such algebras are (algebraically) isomorphic is also studied. When VV and WW are each a finite union of irreducible varieties and a discrete variety in Bd\mathbb{B}_d with d<d<\infty, then an isomorphism between MV\mathcal M_V and MW\mathcal M_W determines a biholomorphism (with multiplier coordinates) between the varieties; and the isomorphism is composition with this function. These maps are automatically weak-* continuous. We present a number of examples showing that the converse fails in several ways. We discuss several special cases in which the converse does hold---particularly, smooth curves and Blaschke sequences. We also discuss the norm closed algebras associated to a variety, and point out some of the differences.

Keywords

Cite

@article{arxiv.1201.4072,
  title  = {Operator algebras for analytic varieties},
  author = {Kenneth R. Davidson and Christopher Ramsey and Orr Shalit},
  journal= {arXiv preprint arXiv:1201.4072},
  year   = {2015}
}

Comments

39 pages. It has come to light that a result of Davidson and Pitts, that the fibre of the maximal ideal space of the multiplier algebra over a point in the open ball consists only of point evaluation, is not true for $d = \infty$. Version 5 addresses this with some minor changes to the $d=\infty$ case. To appear in Trans. Amer. Math. Soc

R2 v1 2026-06-21T20:07:05.312Z