Subvarieties of the tetrablock and von Neumann's inequality

Abstract

We show an interplay between the complex geometry of the tetrablock E and the commuting triples of operators having E as a spectral set. We prove that every distinguished variety in the tetrablock is one-dimensional and can be represented as equationeqn:1 =\ (x1,x2,x3)∈ E \,:\, (x1,x2) ∈ σT(A1*+x3A2\,,\, A2*+x3A1) \, equation where A1,A2 are commuting square matrices of the same order satisfying [A1*,A1]=[A2*,A2] and a norm condition. The converse also holds, i.e, a set of the form (eqn:1) is always a distinguished variety in E. We show that for a triple of commuting operators = (T1,T2,T3) having E as a spectral set, there is a one-dimensional subvariety of E depending on such that von-Neumann's inequality holds, i.e, \[ f(T1,T2,T3)≤ (x1,x2,x3)∈\, |f(x1,x2,x3)|, \] for any holomorphic polynomial f in three variables, provided that T3n→ 0 strongly as n→ ∞. The variety has been shown to have representation like (eqn:1), where A1,A2 are the unique solutions of the operator equations gather* T1-T2*T3=(I-T3*T3)12X1(I-T3*T3)12 and \\ T2-T1*T3=(I-T3*T3)12X2(I-T3*T3)12. gather* We also show that under certain condition, is a distinguished variety in E. We produce an explicit dilation and a concrete functional model for such a triple (T1,T2,T3) in which the unique operators A1,A2 play the main role. Also, we describe a connection of this theory with the distinguished varieties in the bidisc and in the symmetrized bidisc.