Optical networking for quantum key distribution and quantum communications

T. E. Chapuran; P. Toliver; N. A. Peters; J. Jackel; M. S. Goodman; R. J. Runser; S. R. McNown; N. Dallmann; R. J. Hughes; K. P. McCabe; J. E. Nordholt; C. G. Peterson; K. T. Tyagi; L. Mercer; H. Dardy

doi:10.1088/1367-2630/11/10/105001

Optical networking for quantum key distribution and quantum communications

T. E. Chapuran
, P. Toliver
, N. A. Peters
, J. Jackel
, M. S. Goodman
, R. J. Runser
, S. R. McNown
, N. Dallmann
, R. J. Hughes
, K. P. McCabe
, J. E. Nordholt
, C. G. Peterson
, K. T. Tyagi
, L. Mercer
, H. Dardy

Research output: Contribution to journal › Article › peer-review

236 Scopus citations

Abstract

Modern optical networking techniques have the potential to greatly extend the applicability of quantum communications by moving beyond simple point-to-point optical links and by leveraging existing fibre infrastructures. We experimentally demonstrate many of the fundamental capabilities that are required. These include optical-layer multiplexing, switching and routing of quantum signals; quantum key distribution (QKD) in a dynamically reconfigured optical network; and coexistence of quantum signals with strong conventional telecom traffic on the same fibre. We successfully operate QKD at 1310 nm over a fibre shared with four optically amplified data channels near 1550 nm. We identify the dominant impairment as spontaneous anti-Stokes Raman scattering of the strong signals, quantify its impact, and measure and model its propagation through fibre. We describe a quantum networking architecture which can provide the flexibility and scalability likely to be critical for supporting widespread deployment of quantum applications.

Original language	English
Article number	105001
Journal	New Journal of Physics
Volume	11
DOIs	https://doi.org/10.1088/1367-2630/11/10/105001
State	Published - Oct 7 2009
Externally published	Yes

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Chapuran, T. E., Toliver, P., Peters, N. A., Jackel, J., Goodman, M. S., Runser, R. J., McNown, S. R., Dallmann, N., Hughes, R. J., McCabe, K. P., Nordholt, J. E., Peterson, C. G., Tyagi, K. T., Mercer, L., & Dardy, H. (2009). Optical networking for quantum key distribution and quantum communications. New Journal of Physics, 11, Article 105001. https://doi.org/10.1088/1367-2630/11/10/105001

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title = "Optical networking for quantum key distribution and quantum communications",

abstract = "Modern optical networking techniques have the potential to greatly extend the applicability of quantum communications by moving beyond simple point-to-point optical links and by leveraging existing fibre infrastructures. We experimentally demonstrate many of the fundamental capabilities that are required. These include optical-layer multiplexing, switching and routing of quantum signals; quantum key distribution (QKD) in a dynamically reconfigured optical network; and coexistence of quantum signals with strong conventional telecom traffic on the same fibre. We successfully operate QKD at 1310 nm over a fibre shared with four optically amplified data channels near 1550 nm. We identify the dominant impairment as spontaneous anti-Stokes Raman scattering of the strong signals, quantify its impact, and measure and model its propagation through fibre. We describe a quantum networking architecture which can provide the flexibility and scalability likely to be critical for supporting widespread deployment of quantum applications.",

author = "Chapuran, \{T. E.\} and P. Toliver and Peters, \{N. A.\} and J. Jackel and Goodman, \{M. S.\} and Runser, \{R. J.\} and McNown, \{S. R.\} and N. Dallmann and Hughes, \{R. J.\} and McCabe, \{K. P.\} and Nordholt, \{J. E.\} and Peterson, \{C. G.\} and Tyagi, \{K. T.\} and L. Mercer and H. Dardy",

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doi = "10.1088/1367-2630/11/10/105001",

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AU - Chapuran, T. E.

AU - Toliver, P.

AU - Peters, N. A.

AU - Jackel, J.

AU - Goodman, M. S.

AU - Runser, R. J.

AU - McNown, S. R.

AU - Dallmann, N.

AU - Hughes, R. J.

AU - McCabe, K. P.

AU - Nordholt, J. E.

AU - Peterson, C. G.

AU - Tyagi, K. T.

AU - Mercer, L.

AU - Dardy, H.

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AB - Modern optical networking techniques have the potential to greatly extend the applicability of quantum communications by moving beyond simple point-to-point optical links and by leveraging existing fibre infrastructures. We experimentally demonstrate many of the fundamental capabilities that are required. These include optical-layer multiplexing, switching and routing of quantum signals; quantum key distribution (QKD) in a dynamically reconfigured optical network; and coexistence of quantum signals with strong conventional telecom traffic on the same fibre. We successfully operate QKD at 1310 nm over a fibre shared with four optically amplified data channels near 1550 nm. We identify the dominant impairment as spontaneous anti-Stokes Raman scattering of the strong signals, quantify its impact, and measure and model its propagation through fibre. We describe a quantum networking architecture which can provide the flexibility and scalability likely to be critical for supporting widespread deployment of quantum applications.

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Optical networking for quantum key distribution and quantum communications

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