An Evolutionary Pathway for the Quantum Internet Relying on Secure Classical Repeaters
An Evolutionary Pathway for the Quantum Internet Relying on Secure Classical Repeaters
Until quantum repeaters become mature, quantum networks remain restricted either to limited areas of directly connected nodes or to nodes connected to a common node. We circumvent this limitation by conceiving quantum networks using secure classical repeaters combined with the quantum secure direct communication (QSDC) principle, which is a compelling form of quantum communication that directly transmits information over quantum channel. The final component of this promising solution is our classical quantum-resistant algorithm. Explicitly, in these networks, the ciphertext gleaned from a quantum-resistant algorithm is transmitted using QSDC along the nodes, where it is read out and then transmitted to the next node. At the repeaters, the information is protected by our quantum-resistant algorithm, which is secure even in the face of a quantum computer. Hence, our solution offers secure end-to-end communication across the entire network, since it is capable of both eavesdropping
detection and prevention in the emerging quantum internet. It is compatible with operational networks, and will enjoy the compelling services of the popular Internet, including authentication. Hence, it smoothens the transition from the classical Internet to the Quantum Internet (Qinternet) by following a gradual evolutionary upgrade. It will act as an alternative network in quantum computing networks in the future. We have presented the first experimental demonstration of a secure classical repeater based hybrid quantum network constructed by a serial concatenation of an optical fiber and free-space communication link. In conclusion, secure repeater networks
may indeed be constructed using existing technology and continue to support a seamless evolutionary pathway to the future Qinternet of quantum computers.
Long, Gui-Lu
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Pan, Dong
353892b5-b8b3-4f6f-92d5-9d9544b1266e
Sheng, Yu-Bo
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Xue, Qikun
bd0dafa1-80ce-40da-8e5d-6056202829ef
Lu, Jianhua
f1a78bd8-87f4-493c-88f0-10eca43029ba
Hanzo, Lajos
66e7266f-3066-4fc0-8391-e000acce71a1
Long, Gui-Lu
b9a4e55a-8a02-4629-a66d-640aebe2cc78
Pan, Dong
353892b5-b8b3-4f6f-92d5-9d9544b1266e
Sheng, Yu-Bo
14c84942-a862-4619-9e27-13fb2f5b3b46
Xue, Qikun
bd0dafa1-80ce-40da-8e5d-6056202829ef
Lu, Jianhua
f1a78bd8-87f4-493c-88f0-10eca43029ba
Hanzo, Lajos
66e7266f-3066-4fc0-8391-e000acce71a1
Long, Gui-Lu, Pan, Dong, Sheng, Yu-Bo, Xue, Qikun, Lu, Jianhua and Hanzo, Lajos
(2022)
An Evolutionary Pathway for the Quantum Internet Relying on Secure Classical Repeaters.
IEEE Network.
(In Press)
Abstract
Until quantum repeaters become mature, quantum networks remain restricted either to limited areas of directly connected nodes or to nodes connected to a common node. We circumvent this limitation by conceiving quantum networks using secure classical repeaters combined with the quantum secure direct communication (QSDC) principle, which is a compelling form of quantum communication that directly transmits information over quantum channel. The final component of this promising solution is our classical quantum-resistant algorithm. Explicitly, in these networks, the ciphertext gleaned from a quantum-resistant algorithm is transmitted using QSDC along the nodes, where it is read out and then transmitted to the next node. At the repeaters, the information is protected by our quantum-resistant algorithm, which is secure even in the face of a quantum computer. Hence, our solution offers secure end-to-end communication across the entire network, since it is capable of both eavesdropping
detection and prevention in the emerging quantum internet. It is compatible with operational networks, and will enjoy the compelling services of the popular Internet, including authentication. Hence, it smoothens the transition from the classical Internet to the Quantum Internet (Qinternet) by following a gradual evolutionary upgrade. It will act as an alternative network in quantum computing networks in the future. We have presented the first experimental demonstration of a secure classical repeater based hybrid quantum network constructed by a serial concatenation of an optical fiber and free-space communication link. In conclusion, secure repeater networks
may indeed be constructed using existing technology and continue to support a seamless evolutionary pathway to the future Qinternet of quantum computers.
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Accepted/In Press date: 6 February 2022
Identifiers
Local EPrints ID: 454955
URI: http://eprints.soton.ac.uk/id/eprint/454955
ISSN: 0890-8044
PURE UUID: 0ad47419-9da7-4198-800c-3f9fb015a54c
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Date deposited: 02 Mar 2022 17:54
Last modified: 17 Mar 2024 02:35
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Contributors
Author:
Gui-Lu Long
Author:
Dong Pan
Author:
Yu-Bo Sheng
Author:
Qikun Xue
Author:
Jianhua Lu
Author:
Lajos Hanzo
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