# Quantum Reactivity: A Measure of Quantum Correlation

**Authors:** Shahabeddin Mostafanazhad Aslmarand, Warner A. Miller, Paul M. Alsing, and Verinder S. Rana

arXiv: 1902.02391 · 2021-05-21

## TL;DR

This paper introduces quantum reactivity, a new geometric measure of quantum correlation for multipartite states, which is scalable, satisfies key properties, and effectively orders states by their degree of quantum correlation.

## Contribution

The paper proposes a novel, scalable geometric measure called quantum reactivity that extends to large multipartite systems and satisfies all key properties of quantum correlation measures.

## Key findings

- Quantum reactivity is a monotonic function of quantum correlation.
- It satisfies properties like monotonicity and invariance under unitary operations.
- It effectively orders different multipartite quantum states by their correlation degree.

## Abstract

Defining a robust measure of quantum correlation for multipartite states is an unresolved and challenging problem. Existing measures of quantum correlation are either not scalable or do not satisfy all the accepted properties of a measure of quantum correlation. We introduce a novel geometric measure of quantum correlation that we refer to as quantum reactivity. This measure is extendable to an arbitrary large number of qubits and satisfies the required properties of monotonicity and invariance under unitary operations. Our approach is based on generalization of Schumacher's singlet state triangle inequality that used an information geometry--based entropic distance. We define quantum reactivity as the familiar ratio of surface area to volume. To accomplish this, we use a generalization of information distance to area, volume and higher--dimensional volumes. We examine a spectrum of multipartite states (Werner, W, GHZ etc.) and demonstrate that the quantum reactivity measure is a monotonic function for quantum correlation which satisfies all the properties of a measure for quantum correlation, and provides an ordering of these quantum states as to their degree of correlation.

## Full text

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## Figures

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## References

28 references — full list in the complete paper: https://tomesphere.com/paper/1902.02391/full.md

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Source: https://tomesphere.com/paper/1902.02391