Feasibility of phase stabilization for satellite-mediated twin-field quantum key distribution

Joshua J. Collier; David R. Gozzard; John S. Wallis; Shawn M.P. McSorely

doi:10.1364/OL.541228

Feasibility of phase stabilization for satellite-mediated twin-field quantum key distribution

Joshua J. Collier
, David R. Gozzard
, John S. Wallis
, Shawn M.P. McSorely

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

Abstract

Quantum key distribution (QKD) is critical for future proofed secure communication. Satellites will be necessary to mediate QKD on a global scale. The limitations of the existing quantum memory and repeater technology mean that twin-field QKD (TF-QKD) provides the most feasible near-term solution to perform QKD with an untrusted satellite. However, the TF-QKD requires links between ground stations and satellites to be phase stable. We show that phase stabilization of the links to LEO and MEO satellites is feasible in spite of phase noise due to atmospheric turbulence, laser instability, and path length asymmetry while only incurring a quantum bit error rate (QBER) penalty of less than 1.5%. These results are also applicable to future untrusted satellite networks employing precisely synchronized quantum memories or quantum repeaters.

Original language	English
Pages (from-to)	570-573
Number of pages	4
Journal	Optics Letters
Volume	50
Issue number	2
DOIs	https://doi.org/10.1364/OL.541228
Publication status	Published - 15 Jan 2025

Funding

Funders	Funder number
ARC Australian Research Council	CE17010009, DE240100587

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10.1364/OL.541228

Cite this

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title = "Feasibility of phase stabilization for satellite-mediated twin-field quantum key distribution",

abstract = "Quantum key distribution (QKD) is critical for future proofed secure communication. Satellites will be necessary to mediate QKD on a global scale. The limitations of the existing quantum memory and repeater technology mean that twin-field QKD (TF-QKD) provides the most feasible near-term solution to perform QKD with an untrusted satellite. However, the TF-QKD requires links between ground stations and satellites to be phase stable. We show that phase stabilization of the links to LEO and MEO satellites is feasible in spite of phase noise due to atmospheric turbulence, laser instability, and path length asymmetry while only incurring a quantum bit error rate (QBER) penalty of less than 1.5\%. These results are also applicable to future untrusted satellite networks employing precisely synchronized quantum memories or quantum repeaters.",

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note = "Publisher Copyright: {\textcopyright} 2025 Optica Publishing Group. All rights, including for text and data mining (TDM), Artificial Intelligence (AI) training, and similar technologies, are reserved.",

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AU - Wallis, John S.

AU - McSorely, Shawn M.P.

PY - 2025/1/15

Y1 - 2025/1/15

N2 - Quantum key distribution (QKD) is critical for future proofed secure communication. Satellites will be necessary to mediate QKD on a global scale. The limitations of the existing quantum memory and repeater technology mean that twin-field QKD (TF-QKD) provides the most feasible near-term solution to perform QKD with an untrusted satellite. However, the TF-QKD requires links between ground stations and satellites to be phase stable. We show that phase stabilization of the links to LEO and MEO satellites is feasible in spite of phase noise due to atmospheric turbulence, laser instability, and path length asymmetry while only incurring a quantum bit error rate (QBER) penalty of less than 1.5%. These results are also applicable to future untrusted satellite networks employing precisely synchronized quantum memories or quantum repeaters.

AB - Quantum key distribution (QKD) is critical for future proofed secure communication. Satellites will be necessary to mediate QKD on a global scale. The limitations of the existing quantum memory and repeater technology mean that twin-field QKD (TF-QKD) provides the most feasible near-term solution to perform QKD with an untrusted satellite. However, the TF-QKD requires links between ground stations and satellites to be phase stable. We show that phase stabilization of the links to LEO and MEO satellites is feasible in spite of phase noise due to atmospheric turbulence, laser instability, and path length asymmetry while only incurring a quantum bit error rate (QBER) penalty of less than 1.5%. These results are also applicable to future untrusted satellite networks employing precisely synchronized quantum memories or quantum repeaters.

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Feasibility of phase stabilization for satellite-mediated twin-field quantum key distribution

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Feasibility of phase stabilization for satellite-mediated twin-field quantum key distribution

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A quantum telescope for extremely high-resolution imaging

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