Normed ideal perturbation of irreducible operators in semifinite von Neumann factors

Abstract

In [10], Halmos proved an interesting result that the set of irreducible operators is dense in B( H) in the sense of Hilbert-Schmidt approximation. In a von Neumann algebra M with separable predual, an operator a∈ M is said to be irreducible in M if W*(a) is an irreducible subfactor of M, i.e., W*(a)' M= C · I. In this paper, let (·) be a ·-dominating, unitarily invariant norm (see Definition 2.1), where by · we denote the operator norm. We prove that in every semifinite von Neumann factor M with separable predual, if the norm (·) satisfies a natural restriction introduced in (1.1), then irreducible operators are (·)-norm dense in M. In particular, the operator norm · and the \·, ·p\-norm (for each p>1) naturally satisfy the condition in (1.1), where τ is a faithful, normal, semifinite, tracial weight and xp=τ(|x|p)1/p for all x∈ M Lp( M,τ) (see [18, Preliminaries]). This can be viewed as a (stronger) analogue of a theorem of Halmos in [10], proved with different techniques developed in semifinite, properly infinite von Neumann factors. Meanwhile, for every ·-dominating, unitarily invariant norm (·), we develop another method to prove that each normal operator in M is a sum of an irreducible operator in M and an arbitrarily small (·)-norm perturbation, where the (·)-norm isn't restricted by (1.1). Particularly, the (·)-norm can be the \·, ·1\-norm.