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 $C_0$-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 $\sum_j|\langle\varphi_j,ψ_j\rangle-1|$ formed from any pair of representatives. We show that $d$ is well defined on equivalence classes, satisfies the strong tr...
Description / Details
We revisit von Neumann's theory of infinite tensor products of Hilbert spaces. On the set of equivalence classes of -sequences, which labels the incomplete tensor products inside the complete tensor product, we introduce a natural pseudo-ultrametric : the distance between two classes is the convergence exponent of the series formed from any pair of representatives. We show that is well defined on equivalence classes, satisfies the strong triangle inequality, and is complete. Distinct classes may lie at distance zero, so separates points only after passing to the quotient of by the relation ; the pair is then a complete ultrametric space. As an application, we show that a product unitary whose factor satisfies (in particular, a unitary on a finite dimensional space with ) displaces every class to the maximal distance . 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 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 , is class dependent and realizes every value in . We interpret 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.
Source: arXiv:2607.09627v1 - http://arxiv.org/abs/2607.09627v1 PDF: https://arxiv.org/pdf/2607.09627v1 Original Link: http://arxiv.org/abs/2607.09627v1
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Jul 13, 2026
Quantum Computing
Quantum Physics
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