A complete ultrametric on von Neumann's incomplete tensor products

Abstract

We revisit von Neumann's theory of infinite tensor products of Hilbert spaces. On the set Γ of equivalence classes of C0-sequences, which labels the incomplete tensor products inside the complete tensor product, we introduce a natural pseudo-ultrametric d: the distance between two classes is the convergence exponent of the series Σj|φj,ψj-1| formed from any pair of representatives. We show that d is well defined on equivalence classes, satisfies the strong triangle inequality, and is complete. Distinct classes may lie at distance zero, so d separates points only after passing to the quotient Γ of Γ by the relation d=0; the pair (Γ,d) is then a complete ultrametric space. As an application, we show that a product unitary j U whose factor U satisfies ∈f\|x\|=1| x,Ux-1|>0 (in particular, a unitary on a finite dimensional space with 1σ(U)) displaces every class to the maximal distance 1. Guided by the intended application -- a caricature of Everettian branching, in which the sectors of the infinite tensor product play the role of worlds -- we also develop a gauge-invariant variant d of the metric, based on von Neumann's weak equivalence and matched to the quasi-equivalence of product states on the quasi-local algebra. The displacement of a class under a product unitary, measured by d, is class dependent and realizes every value in [0,1]. We interpret d as a decoherence exponent: it measures the polynomial rate at which two branches of the universal state vector become operationally distinct as ever larger portions of the environment are monitored.

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