Utilizing broadband wavelength-division multiplexing capabilities of hollow-core fiber for quantum communications
Utilizing broadband wavelength-division multiplexing capabilities of hollow-core fiber for quantum communications
One of the major challenges in the deployment of quantum communications (QC) over solid-core silica optical fiber is the performance degradation due to the optical noise generated with co-propagating classical optical signals. To reduce the impact of the optical noise, research teams are turning to new and novel architectures of solid-core and hollow-core optical fiber. We studied the impact when co-propagating a single-photon level (850 nm) and two classical optical signals (940 nm and 1550 nm) while utilizing a nested antiresonant nodeless fiber (NANF) with two low-loss windows. The 940 nm signal was shown to impact the single-photon measurement due to the silicon detector technology implemented; however, multiplexing techniques and filtering could reduce the impact. The 1550 nm signal was shown to have no detrimental impact. The results highlight that both high bandwidth optical traffic at 1550 nm and a QC channel at 850 nm could co-propagate without degradation to the QC channel.
8959-8966
Nasti, Umberto
546e9167-93cb-47ef-b27b-2ec2559c0e26
Sakr, Hesham
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Davidson, Ian A.
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Poletti, Francesco
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Donaldson, Ross J.
392e36f2-d263-47d1-ad93-5f5940d59338
14 October 2022
Nasti, Umberto
546e9167-93cb-47ef-b27b-2ec2559c0e26
Sakr, Hesham
5ec2d89f-ab6e-4690-bbfd-b95fa4cb792d
Davidson, Ian A.
b685f949-e9e4-4e6b-9a59-36739de06a61
Poletti, Francesco
9adcef99-5558-4644-96d7-ce24b5897491
Donaldson, Ross J.
392e36f2-d263-47d1-ad93-5f5940d59338
Nasti, Umberto, Sakr, Hesham, Davidson, Ian A., Poletti, Francesco and Donaldson, Ross J.
(2022)
Utilizing broadband wavelength-division multiplexing capabilities of hollow-core fiber for quantum communications.
Applied Optics, 61 (30), .
(doi:10.1364/AO.471632).
Abstract
One of the major challenges in the deployment of quantum communications (QC) over solid-core silica optical fiber is the performance degradation due to the optical noise generated with co-propagating classical optical signals. To reduce the impact of the optical noise, research teams are turning to new and novel architectures of solid-core and hollow-core optical fiber. We studied the impact when co-propagating a single-photon level (850 nm) and two classical optical signals (940 nm and 1550 nm) while utilizing a nested antiresonant nodeless fiber (NANF) with two low-loss windows. The 940 nm signal was shown to impact the single-photon measurement due to the silicon detector technology implemented; however, multiplexing techniques and filtering could reduce the impact. The 1550 nm signal was shown to have no detrimental impact. The results highlight that both high bandwidth optical traffic at 1550 nm and a QC channel at 850 nm could co-propagate without degradation to the QC channel.
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ao-61-30-8959
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More information
Accepted/In Press date: 12 September 2022
Published date: 14 October 2022
Additional Information:
Funding Information:
Engineering and Physical Sciences Research Council (EP/P030181/1, EP/T001011/1); Royal Academy of Engineering (RF\201718\1746); European Research Council (682724). The Heriot-Watt University authors would like to acknowledge and thank the Airguide Photonics team for their support in this project.
Identifiers
Local EPrints ID: 481523
URI: http://eprints.soton.ac.uk/id/eprint/481523
ISSN: 1559-128X
PURE UUID: 1d053125-7980-4e7a-b161-6035a84f9005
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Date deposited: 31 Aug 2023 16:41
Last modified: 18 Mar 2024 03:44
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Contributors
Author:
Umberto Nasti
Author:
Hesham Sakr
Author:
Ian A. Davidson
Author:
Francesco Poletti
Author:
Ross J. Donaldson
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