Nicholas Dallmann scite author profile

Abstract. To move beyond dedicated links and networks, quantum communications signals must be integrated into networks carrying classical optical channels at power levels many orders of magnitude higher than the quantum signals themselves. We demonstrate the transmission of a 1550 nm quantum channel with up to two simultaneous 200 GHz spaced classical telecom channels, using reconfigurable optical add drop multiplexer (ROADM) technology for multiplexing and routing quantum and classical signals. The quantum channel is used to perform quantum key distribution (QKD) in the presence of noise generated as a by-product of the co-propagation of classical channels. We demonstrate that the dominant noise mechanism can arise from either four-wave mixing or spontaneous Raman scattering, depending on the optical path characteristics as well as the classical channel parameters. We quantify these impairments and discuss mitigation strategies.

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Practical long-distance quantum key distribution system using decoy levels

Rosenberg¹,

Peterson²,

Harrington³

et al. 2009

New J. Phys.

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Quantum key distribution (QKD) has the potential for widespread real-world applications. To date no secure long-distance experiment has demonstrated the truly practical operation needed to move QKD from the laboratory to the real world due largely to limitations in synchronization and poor detector performance. Here we report results obtained using a fully automated, robust QKD system based on the Bennett Brassard 1984 protocol (BB84)[1] with low-noise superconducting nanowire single-photon detectors (SNSPDs) and decoy levels.Secret key is produced with unconditional security over a record 144.3 km of optical fibre, an increase of more than a factor of five compared to the previous record for unconditionally secure key generation in a practical QKD system.

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A Cs2LiYCl6:Ce-based advanced radiation monitoring device

Budden

Stonehill

Dallmann

et al. 2015

Nuclear Instruments and Methods in Physics Research Section A:

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Experimental characterization of the separation between wavelength-multiplexed quantum and classical communication channels

Nweke

Toliver²,

Runser³

et al. 2005

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Quantum key distribution ͑QKD͒ is a new technique for secure key distribution based on the laws of physics rather than mathematical or algorithmic computational complexity used by current systems. Understanding the compatibility of QKD at 1310 nm with the existing commercial optical networks bearing classical wavelength-division-multiplexed ͑WDM͒ channels at 1550 nm is important to advance the deployment of QKD systems in such networks. The minimum wavelength separation for multiplexing QKD and WDM channels on a shared fiber is experimentally determined for impairment-free QKD+ WDM transmission.

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