Operational Quantification of Continuous Variable Correlations
Abstract
We quantify correlations (quantum and/or classical) between two continuous variable modes in terms of how many correlated bits can be extracted by measuring the sign of two local quadratures. On Gaussian states, such `bit quadrature correlations' majorize entanglement, reducing to an entanglement monotone for pure states. For non-Gaussian states, such as photonic Bell states, ideal and real de-Gaussified photon-subtracted states, and mixtures of pure Gaussian states, the bit correlations are shown to be a {\em monotonic} function of the negativity. This yields a feasible, operational way to quantitatively measure non-Gaussian entanglement in current experiments by means of direct homodyne detection, without a full tomographical reconstruction of the Wigner function.
Cite
@article{arxiv.0707.2811,
title = {Operational Quantification of Continuous Variable Correlations},
author = {C. Rodó and Gerardo Adesso and A. Sanpera},
journal= {arXiv preprint arXiv:0707.2811},
year = {2008}
}
Comments
4 pages, 3 figures, improved presentation, a subfigure and some explicit analytical expressions added