High fidelity distribution of telecom polarization entangled photons through a 7.7 km antiresonant hollow-core fiber
High fidelity distribution of telecom polarization entangled photons through a 7.7 km antiresonant hollow-core fiber
Antiresonant hollow-core fibers are a novel type of optical fiber with unparalleled characteristics, unattainable with solid-core fibers. In particular, antiresonant hollow-core fibers are characterized by vacuum-like propagation speed, suppressed dispersion and nonlinear optical effects and, recently, even ultra-low propagation loss. In recent years, the development of a type of antiresonant hollow-core fiber, called Nested Antiresonant Nodeless Fiber (NANF) has seen tremendous improvements, and applications in both classical and quantum communications have been suggested. While encouraging results over meter long distances have been shown, the distribution of polarized entangled photons over inner-city distances through antiresonant hollow-core fibers has not been demonstrated yet. This could be a game changer for the development of quantum networks, which leverage entanglement for the distribution of secret keys, and more in the long term, in a quantum internet scenario. In this work, an experimental investigation of entanglement distribution through a NANF with an overall length of 7.72 km is presented. Remarkably, substantial reduction of latency (about 13 μs) and suppressed chromatic dispersion (about one order of magnitude) of the studied NANF compared to a telecom single-mode fiber (Corning's SMF28) of equal length are measured for different bandwidths of the distributed entangled photons. Moreover, by encoding entanglement in polarization, high fidelity (>95%) distribution of narrow-bandwidth entangled photons is demonstrated. This result paves the way to the exploitation of NANF as a superior transmitting medium for quantum technology applications relying on the distribution of entanglement encoded in polarization over inner-city distances.
Hollow-core fiber, Nested Antiresonant Nodeless Fiber (NANF), quantum communication, quantum cryptography, quantum entanglement, qubit, SPAD
Trenti, Alessandro
d00c172e-7664-4068-8564-5317a71cbe13
Luchian, Costin
84aea78b-06b0-48ae-9cbb-027720a9eadf
Poletti, Francesco
9adcef99-5558-4644-96d7-ce24b5897491
Slavik, Radan
2591726a-ecc0-4d1a-8e1d-4d0fd8da8f7d
Petropoulos, Periklis
522b02cc-9f3f-468e-bca5-e9f58cc9cad7
Alia, Obada
316fbef1-4ad0-4716-9419-4c481b42fa3c
22 April 2024
Trenti, Alessandro
d00c172e-7664-4068-8564-5317a71cbe13
Luchian, Costin
84aea78b-06b0-48ae-9cbb-027720a9eadf
Poletti, Francesco
9adcef99-5558-4644-96d7-ce24b5897491
Slavik, Radan
2591726a-ecc0-4d1a-8e1d-4d0fd8da8f7d
Petropoulos, Periklis
522b02cc-9f3f-468e-bca5-e9f58cc9cad7
Alia, Obada
316fbef1-4ad0-4716-9419-4c481b42fa3c
Trenti, Alessandro, Luchian, Costin, Poletti, Francesco, Slavik, Radan, Petropoulos, Periklis and Alia, Obada
(2024)
High fidelity distribution of telecom polarization entangled photons through a 7.7 km antiresonant hollow-core fiber.
IEEE Journal of Selected Topics in Quantum Electronics, 30 (6), [6400308].
(doi:10.1109/JSTQE.2024.3392416).
Abstract
Antiresonant hollow-core fibers are a novel type of optical fiber with unparalleled characteristics, unattainable with solid-core fibers. In particular, antiresonant hollow-core fibers are characterized by vacuum-like propagation speed, suppressed dispersion and nonlinear optical effects and, recently, even ultra-low propagation loss. In recent years, the development of a type of antiresonant hollow-core fiber, called Nested Antiresonant Nodeless Fiber (NANF) has seen tremendous improvements, and applications in both classical and quantum communications have been suggested. While encouraging results over meter long distances have been shown, the distribution of polarized entangled photons over inner-city distances through antiresonant hollow-core fibers has not been demonstrated yet. This could be a game changer for the development of quantum networks, which leverage entanglement for the distribution of secret keys, and more in the long term, in a quantum internet scenario. In this work, an experimental investigation of entanglement distribution through a NANF with an overall length of 7.72 km is presented. Remarkably, substantial reduction of latency (about 13 μs) and suppressed chromatic dispersion (about one order of magnitude) of the studied NANF compared to a telecom single-mode fiber (Corning's SMF28) of equal length are measured for different bandwidths of the distributed entangled photons. Moreover, by encoding entanglement in polarization, high fidelity (>95%) distribution of narrow-bandwidth entangled photons is demonstrated. This result paves the way to the exploitation of NANF as a superior transmitting medium for quantum technology applications relying on the distribution of entanglement encoded in polarization over inner-city distances.
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e-pub ahead of print date: 22 April 2024
Published date: 22 April 2024
Keywords:
Hollow-core fiber, Nested Antiresonant Nodeless Fiber (NANF), quantum communication, quantum cryptography, quantum entanglement, qubit, SPAD
Identifiers
Local EPrints ID: 502964
URI: http://eprints.soton.ac.uk/id/eprint/502964
ISSN: 1077-260X
PURE UUID: b5e18451-ada9-49c2-9288-0064a6066137
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Date deposited: 15 Jul 2025 16:39
Last modified: 16 Jul 2025 01:43
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Contributors
Author:
Alessandro Trenti
Author:
Costin Luchian
Author:
Francesco Poletti
Author:
Radan Slavik
Author:
Periklis Petropoulos
Author:
Obada Alia
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