Classical noise and the structure of minimal uncertainty states

TL;DR

This paper investigates the existence and structure of states that minimize uncertainty across various measures in quantum systems, especially under classical noise, revealing limitations and potential for approximate universality.

Contribution

It introduces axioms for uncertainty functions, proves non-existence of universal minimal uncertainty states in full space, and explores how classical noise influences their structure.

Findings

Universal MUS do not exist in full state space.

Classical noise can enable the existence of universal MUS in qubits.

Higher-dimensional systems face no-go results limiting noisy universal MUS.

Abstract

Which quantum states minimise the unavoidable uncertainty arising from the non-commutativity of two observables? The immediate answer to such a question is: it depends. Due to the plethora of uncertainty measures there are many answers. Here, instead of restricting our study to a particular measure, we present plausible axioms for the set $\mathcal{F}$ of bona-fide information-theoretic uncertainty functions. Then, we discuss the existence of states minimising uncertainty with respect to all members of $\mathcal{F}$, i.e., universal minimum uncertainty states (MUS). We prove that such states do not exist within the full state space and study the effect of classical noise on the structure of minimum uncertainty states. We present an explicit example of a qubit universal MUS that arises when purity is constrained by introducing a threshold amount of noise. For higher dimensional systems we derive several no-go results limiting the existence of noisy universal MUS. However, we conjecture that universality may emerge in an approximate sense. We conclude by discussing connections with thermodynamics, and highlight the privileged role that non-equilibrium free energy $F_2$ plays close to equilibrium.