# Partial Transposition in a Finite-Dimensional Hilbert Space: Physical   Interpretation, Measurement of Observables and Entanglement

**Authors:** Yehuda B. Band, Pier A. Mello

arXiv: 1705.09613 · 2017-05-29

## TL;DR

This paper links partial transposition in finite-dimensional quantum systems to a sign change in a momentum-like variable in the Wigner function, providing a physical interpretation and measurement approach for entanglement detection.

## Contribution

It generalizes the continuous-variable partial transposition result to discrete systems and shows how to measure observables in partially transposed states.

## Key findings

- Partial transposition corresponds to a sign change in a momentum-like variable in the Wigner function.
- Quantum mechanics allows measuring expectation values in non-physical, partially transposed states.
- Negative variance in an observable indicates entanglement in the studied states.

## Abstract

We show that partial transposition for pure and mixed two-particle states in a discrete $N$-dimensional Hilbert space is equivalent to a change in sign of a "momentum-like" variable of one of the particles in the Wigner function for the state. This generalizes a result obtained for continuous-variable systems to the discrete-variable system case. We show that, in principle, quantum mechanics allows measuring the expectation value of an observable in a partially transposed state, in spite of the fact that the latter may not be a physical state. We illustrate this result with the example of an "isotropic state", which is dependent on a parameter $r$, and an operator whose variance becomes negative for the partially transposed state for certain values of $r$; for such $r$, the original states are entangled.

## Full text

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## References

21 references — full list in the complete paper: https://tomesphere.com/paper/1705.09613/full.md

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Source: https://tomesphere.com/paper/1705.09613