Collapse of the quantum correlation hierarchy links entropic uncertainty to entanglement creation

TL;DR

This paper reveals that for certain bipartite states, the hierarchy of quantum correlation measures collapses, linking entropic uncertainty directly to entanglement creation during measurement, and reinterpreting uncertainty relations.

Contribution

It introduces premeasurement states where quantum correlation hierarchies collapse, connecting entropic uncertainty to entanglement generation and providing new insights into measurement-induced quantum correlations.

Findings

Hierarchy collapse links uncertainty to quantum correlations.

Entropic uncertainty relations bound entanglement creation.

Measurement interactions produce states with unified quantum correlation measures.

Abstract

Quantum correlations have fundamental and technological interest, and hence many measures have been introduced to quantify them. Some hierarchical orderings of these measures have been established, e.g., discord is bigger than entanglement, and we present a class of bipartite states, called premeasurement states, for which several of these hierarchies collapse to a single value. Because premeasurement states are the kind of states produced when a system interacts with a measurement device, the hierarchy collapse implies that the uncertainty of an observable is quantitatively connected to the quantum correlations (entanglement, discord, etc.) produced when that observable is measured. This fascinating connection between uncertainty and quantum correlations leads to a reinterpretation of entropic formulations of the uncertainty principle, so-called entropic uncertainty relations, including ones that allow for quantum memory. These relations can be thought of as lower-bounds on the entanglement created when incompatible observables are measured. Hence, we find that entanglement creation exhibits complementarity, a concept that should encourage exploration into "entanglement complementarity relations".