Noncommutative functions are weakly algebraic on operatorial polynomial polyhedra

Abstract

An operatorial polynomial polyhedron is a set of the form Bδ(B(H))=\X∈ B(H)d : δ(X)<1\ where B(H) denotes the space of bounded operators on a separable Hilbert space H, and δ is a matrix of polynomials in d noncommuting variables. These sets appear throughout the literature on noncommutative function theory. While much of what has been written involves matricial polynomial polyhedra, there do exist δ such that the associated Bδ(B(H)) is non-empty but contains no matrix points. Algebraicity of operatorial noncommutative functions has been established in the case that the domain Bδ(B(H)) is a balanced set (hence contains the matrix point 0). In this paper, we dispense of such assumptions on the domain and prove that an operatorial noncommutative function on any Bδ(B(H)) is weakly algebraic in the sense that its value at each operator tuple Z lies in the weak operator topology closure of the unital algebra generated by the coordinates of Z.