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Quantum Information Processing

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01-05-2016

Revealing quantum correlation by negativity of the Wigner function

Authors: Razieh Taghiabadi, Seyed Javad Akhtarshenas, Mohsen Sarbishaei

Published in: Quantum Information Processing | Issue 5/2016

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Abstract

We analyze two two-mode continuous variable separable states with the same marginal states. We adopt the definition of classicality in the form of well-defined positive Wigner function describing the state and find that although the states possess positive local Wigner functions, they exhibit negative Wigner functions for the global states. Using the negativity of Wigner function as an indicator of nonclassicality, we show that despite these states possess different negativities of the Wigner function, they do not reveal this difference as phase space nonclassicalities such as negativity of the Mandel Q parameter or quadrature squeezing. We then concentrate on quantum correlation of these states and show that quantum discord and local quantum uncertainty, as two well-defined measures of quantum correlation, manifest the difference between negativity of the Wigner functions. The non-Gaussianity of these states is also examined and show that the difference in behavior of their non-Gaussianity is the same as the difference between negativity of their Wigner functions. We also investigate the influence of correlation rank criterion and find that when the states can be produced locally from classical states, the Wigner functions cannot reveal their quantum correlations.

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Title: Revealing quantum correlation by negativity of the Wigner function
Authors: Razieh Taghiabadi
Seyed Javad Akhtarshenas
Mohsen Sarbishaei
Publication date: 01-05-2016
Publisher: Springer US
Published in: Quantum Information Processing / Issue 5/2016
Print ISSN: 1570-0755
Electronic ISSN: 1573-1332
DOI: https://doi.org/10.1007/s11128-016-1255-6

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