A device-independent quantum key distribution system for distant users

Research output: Contribution to journalArticleResearchpeer review

Authors

  • Wei Zhang
  • Tim van Leent
  • Kai Redeker
  • Robert Garthoff
  • René Schwonnek
  • Florian Fertig
  • Sebastian Eppelt
  • Wenjamin Rosenfeld
  • Valerio Scarani
  • Charles C.W. Lim
  • Harald Weinfurter

External Research Organisations

  • Ludwig-Maximilians-Universität München (LMU)
  • Munich Center for Quantum Science and Technology (MCQST)
  • University of Siegen
  • National University of Singapore
  • JPMorgan Chase & Co.
  • Max Planck Institute of Quantum Optics (MPQ)
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Details

Original languageEnglish
Pages (from-to)687-691
Number of pages5
JournalNATURE
Volume607
Issue number7920
Early online date27 Jul 2022
Publication statusPublished - 28 Jul 2022
Externally publishedYes

Abstract

Device-independent quantum key distribution (DIQKD) enables the generation of secret keys over an untrusted channel using uncharacterized and potentially untrusted devices1–9. The proper and secure functioning of the devices can be certified by a statistical test using a Bell inequality10–12. This test originates from the foundations of quantum physics and also ensures robustness against implementation loopholes13, thereby leaving only the integrity of the users’ locations to be guaranteed by other means. The realization of DIQKD, however, is extremely challenging—mainly because it is difficult to establish high-quality entangled states between two remote locations with high detection efficiency. Here we present an experimental system that enables for DIQKD between two distant users. The experiment is based on the generation and analysis of event-ready entanglement between two independently trapped single rubidium atoms located in buildings 400 metre apart14. By achieving an entanglement fidelity of ℱ≥0.892(23) and implementing a DIQKD protocol with random key basis15, we observe a significant violation of a Bell inequality of S = 2.578(75)—above the classical limit of 2—and a quantum bit error rate of only 0.078(9). For the protocol, this results in a secret key rate of 0.07 bits per entanglement generation event in the asymptotic limit, and thus demonstrates the system’s capability to generate secret keys. Our results of secure key exchange with potentially untrusted devices pave the way to the ultimate form of quantum secure communications in future quantum networks.

ASJC Scopus subject areas

Cite this

A device-independent quantum key distribution system for distant users. / Zhang, Wei; van Leent, Tim; Redeker, Kai et al.
In: NATURE, Vol. 607, No. 7920, 28.07.2022, p. 687-691.

Research output: Contribution to journalArticleResearchpeer review

Zhang, W, van Leent, T, Redeker, K, Garthoff, R, Schwonnek, R, Fertig, F, Eppelt, S, Rosenfeld, W, Scarani, V, Lim, CCW & Weinfurter, H 2022, 'A device-independent quantum key distribution system for distant users', NATURE, vol. 607, no. 7920, pp. 687-691. https://doi.org/10.48550/arXiv.2110.00575, https://doi.org/10.1038/s41586-022-04891-y
Zhang, W., van Leent, T., Redeker, K., Garthoff, R., Schwonnek, R., Fertig, F., Eppelt, S., Rosenfeld, W., Scarani, V., Lim, C. C. W., & Weinfurter, H. (2022). A device-independent quantum key distribution system for distant users. NATURE, 607(7920), 687-691. https://doi.org/10.48550/arXiv.2110.00575, https://doi.org/10.1038/s41586-022-04891-y
Zhang W, van Leent T, Redeker K, Garthoff R, Schwonnek R, Fertig F et al. A device-independent quantum key distribution system for distant users. NATURE. 2022 Jul 28;607(7920):687-691. Epub 2022 Jul 27. doi: 10.48550/arXiv.2110.00575, 10.1038/s41586-022-04891-y
Zhang, Wei ; van Leent, Tim ; Redeker, Kai et al. / A device-independent quantum key distribution system for distant users. In: NATURE. 2022 ; Vol. 607, No. 7920. pp. 687-691.
Download
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abstract = "Device-independent quantum key distribution (DIQKD) enables the generation of secret keys over an untrusted channel using uncharacterized and potentially untrusted devices1–9. The proper and secure functioning of the devices can be certified by a statistical test using a Bell inequality10–12. This test originates from the foundations of quantum physics and also ensures robustness against implementation loopholes13, thereby leaving only the integrity of the users{\textquoteright} locations to be guaranteed by other means. The realization of DIQKD, however, is extremely challenging—mainly because it is difficult to establish high-quality entangled states between two remote locations with high detection efficiency. Here we present an experimental system that enables for DIQKD between two distant users. The experiment is based on the generation and analysis of event-ready entanglement between two independently trapped single rubidium atoms located in buildings 400 metre apart14. By achieving an entanglement fidelity of ℱ≥0.892(23) and implementing a DIQKD protocol with random key basis15, we observe a significant violation of a Bell inequality of S = 2.578(75)—above the classical limit of 2—and a quantum bit error rate of only 0.078(9). For the protocol, this results in a secret key rate of 0.07 bits per entanglement generation event in the asymptotic limit, and thus demonstrates the system{\textquoteright}s capability to generate secret keys. Our results of secure key exchange with potentially untrusted devices pave the way to the ultimate form of quantum secure communications in future quantum networks.",
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note = "Funding information: We thank I. W. Primaatmaja, E. Y.-Z. Tan and K. T. Goh for useful inputs and discussions. W.Z., T.v.L., K.R., R.G., F.F., S.E., W.R. and H.W. acknowledge funding by the German Federal Ministry of Education and Research (Bundesministerium f{\"u}r Bildung und Forschung (BMBF)) within the project Q.Link.X (16KIS0880), QR.X (16KISQ002) the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) under Germany{\textquoteright}s Excellence Strategy (EXC-2111–390814868) and the Alexander von Humboldt foundation. C.C.-W.L. and R.S. are funded by the National Research Foundation, Singapore, under its NRF Fellowship programme (NRFF11-2019-0001) and NRF Quantum Engineering Programme 1.0 (QEP-P2). V.S. and C.C.-W.L. acknowledge support from the National Research Foundation and the Ministry of Education, Singapore, under the Research Centres of Excellence programme.",
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AU - Zhang, Wei

AU - van Leent, Tim

AU - Redeker, Kai

AU - Garthoff, Robert

AU - Schwonnek, René

AU - Fertig, Florian

AU - Eppelt, Sebastian

AU - Rosenfeld, Wenjamin

AU - Scarani, Valerio

AU - Lim, Charles C.W.

AU - Weinfurter, Harald

N1 - Funding information: We thank I. W. Primaatmaja, E. Y.-Z. Tan and K. T. Goh for useful inputs and discussions. W.Z., T.v.L., K.R., R.G., F.F., S.E., W.R. and H.W. acknowledge funding by the German Federal Ministry of Education and Research (Bundesministerium für Bildung und Forschung (BMBF)) within the project Q.Link.X (16KIS0880), QR.X (16KISQ002) the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) under Germany’s Excellence Strategy (EXC-2111–390814868) and the Alexander von Humboldt foundation. C.C.-W.L. and R.S. are funded by the National Research Foundation, Singapore, under its NRF Fellowship programme (NRFF11-2019-0001) and NRF Quantum Engineering Programme 1.0 (QEP-P2). V.S. and C.C.-W.L. acknowledge support from the National Research Foundation and the Ministry of Education, Singapore, under the Research Centres of Excellence programme.

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