Characterizing quantum channels with non-separable states of classical light

High-dimensional entanglement with spatial modes of light promises increased security and information capacity over quantum channels. Unfortunately, entanglement decays due to perturbations, corrupting quantum links that cannot be repaired without performing quantum tomography on the channel. Parado...

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Bibliographic Details
Published in:Nature physics 2017-04, Vol.13 (4), p.397-402
Main Authors: Ndagano, Bienvenu, Perez-Garcia, Benjamin, Roux, Filippus S., McLaren, Melanie, Rosales-Guzman, Carmelo, Zhang, Yingwen, Mouane, Othmane, Hernandez-Aranda, Raul I., Konrad, Thomas, Forbes, Andrew
Format: Article
Language:English
Subjects:
639/624/400/3925
639/766/483/1139
Atmosphere
Atomic
Channels
Classical and Continuum Physics
Complex Systems
Condensed Matter Physics
Decay
Entanglement
Links
Mathematical and Computational Physics
Molecular
Optical and Plasma Physics
Optics
Photons
Physics
Quantum physics
Theoretical
Tomography
Trajectories
Turbulent flow
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Summary:High-dimensional entanglement with spatial modes of light promises increased security and information capacity over quantum channels. Unfortunately, entanglement decays due to perturbations, corrupting quantum links that cannot be repaired without performing quantum tomography on the channel. Paradoxically, the channel tomography itself is not possible without a working link. Here we overcome this problem with a robust approach to characterize quantum channels by means of classical light. Using free-space communication in a turbulent atmosphere as an example, we show that the state evolution of classically entangled degrees of freedom is equivalent to that of quantum entangled photons, thus providing new physical insights into the notion of classical entanglement. The analysis of quantum channels by means of classical light in real time unravels stochastic dynamics in terms of pure state trajectories, and thus enables precise quantum error correction in short- and long-haul optical communication, in both free space and fibre. Classical light is as good as quantum light to characterize a quantum channel. This unexpected result has practical consequences that make an experimentalist’s life easier in some situations.
ISSN:1745-2473
1745-2481
DOI:10.1038/nphys4003