# Entanglement production by statistical operators

**Authors:** V.I. Yukalov, E.P. Yukalova, and V.A. Yurovsky

arXiv: 1904.08294 · 2019-05-22

## TL;DR

This paper introduces a measure of entanglement production by statistical operators, linking it to quantum information concepts and analyzing its behavior in various quantum systems and partitions.

## Contribution

It defines and illustrates a measure of entanglement production by statistical operators, connecting it with existing quantum information measures and exploring its properties in different quantum systems.

## Key findings

- The measure relates to purity, entropy, and decoherence.
- Conditions for maximal and zero entanglement production are established.
- Application to multiparticle and spinor systems demonstrates the measure's versatility.

## Abstract

In the problem of entanglement there exist two different notions. One is the entanglement of a quantum state, characterizing the state structure. The other is entanglement production by quantum operators, describing the action of operators in the given Hilbert space. Entanglement production by statistical operators, or density operators, is an important notion arising in quantum measurements and quantum information processing. The operational meaning of the entangling power of any operator, including statistical operators, is the property of the operators to entangle wave functions of the Hilbert space they are defined on. The measure of entanglement production by statistical operators is described and illustrated by entangled quantum states, equilibrium Gibbs states, as well as by the state of a complex multiparticle spinor system. It is shown that this measure is in intimate relation to other notions of quantum information theory, such as the purity of quantum states, linear entropy, or impurity, inverse participation ratio, quadratic R\'{e}nyi entropy, the correlation function of composite measurements, and decoherence phenomenon. This measure can be introduced for a set of statistical operators characterizing a system after quantum measurements. The explicit value of the measure depends on the type of the Hilbert space partitioning. For a general multiparticle spinor system, it is possible to accomplish the particle-particle partitioning or spin-spatial partitioning. Conditions are defined showing when entanglement production is maximal and when it is zero. The study on entanglement production by statistical operators is important because, depending on whether such an operator is entangling or not, it generates qualitatively different probability measures, which is principal for quantum measurements and quantum information processing.

## Full text

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## Figures

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## References

101 references — full list in the complete paper: https://tomesphere.com/paper/1904.08294/full.md

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