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Experimental Demonstration of High-Rate Measurement-Device-Independent Quantum Key Distribution over Asymmetric Channels
Hui Liu, Wenyuan Wang, Kejin Wei, Xiao-Tian Fang, Li Li, Nai-Le Liu, Hao Liang, Si-Jie Zhang, Weijun Zhang, Hao Li, Lixing You, Zhen Wang, Hoi-Kwong Lo, Teng-Yun Chen, Feihu Xu, and Jian-Wei Pan
Phys. Rev. Lett. 122, 160501 – Published 26 April 2019
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Abstract
Measurement-device-independent quantum key distribution (MDI-QKD) can eliminate all detector side channels and it is practical with current technology. Previous implementations of MDI-QKD all used two symmetric channels with similar losses. However, the secret key rate is severely limited when different channels have different losses. Here we report the results of the first high-rate MDI-QKD experiment over asymmetric channels. By using the recent 7-intensity optimization approach, we key rate than the previous best-known protocols for MDI-QKD in the situation of large channel asymmetry, and extend the secure transmission distance by more than 20–50km in standard telecom fiber. The results have moved MDI-QKD towards widespread applications in practical network settings, where the channel losses are asymmetric and user nodes could be dynamically added or deleted.
- Received 6 September 2018
DOI:https://doi.org/10.1103/PhysRevLett.122.160501
© 2019 American Physical Society
Physics Subject Headings (PhySH)
- Research Areas
Quantum cryptographyQuantum networks
Quantum Information, Science & Technology
Authors & Affiliations
Hui Liu1,2,*, Wenyuan Wang3,*, Kejin Wei1,2, Xiao-Tian Fang1,2, Li Li1,2, Nai-Le Liu1,2, Hao Liang1,2, Si-Jie Zhang1,2, Weijun Zhang4, Hao Li4, Lixing You4, Zhen Wang4, Hoi-Kwong Lo3, Teng-Yun Chen1,2, Feihu Xu1,2, and Jian-Wei Pan1,2
- 1Shanghai Branch, Hefei National Laboratory for Physical Sciences at Microscale and Department of Modern Physics, University of Science and Technology of China, Shanghai 201315, China
- 2CAS Center for Excellence and Synergetic Innovation Center in Quantum Information and Quantum Physics, University of Science and Technology of China, Shanghai 201315, People’s Republic of China
- 3Centre for Quantum Information and Quantum Control (CQIQC), Department of Electrical & Computer Engineering and Department of Physics, University of Toronto, Toronto, Ontario M5S 3G4, Canada
- 4State Key Laboratory of Functional Materials for Informatics, Shanghai Institute of Microsystem and Information Technology, Chinese Academy of Sciences, Shanghai 200050, China
- *These author contributed equally to this work.
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Issue
Vol. 122, Iss. 16 — 26 April 2019
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Images
Figure 1
An illustration of a star-type MDI-QKD network providing six users with access to the untrusted relay, Charlie. Inset: an example of the possible implementation by Charlie.
Figure 2
MDI-QKD setup. Alice’s (Bob’s) signal laser pulses are modulated into signal and decoy intensities by three amplitude modulators (AM1-AM3). Key bits are encoded by a Mach-Zehnder interferometer, AM4, and a phase modulator (PM). In Charlie, the polarization stabilization system in each link includes an electric polarization controller (EPC), a polarization beam splitter (PBS) and a superconducting nanowire single-photon detector (SNSPD); the Bell state measurement (BSM) system includes a beam splitter (BS), SNSPD1 and SNSPD2. Abbreviations of other components: DWDM, dense wavelength division multiplexer; ConSys, control system; ATT, attenuator; PSL, phase-stabilization laser; Circ, circulator; PC, polarization controller; PS, phase shifter; SPAPD, single-photon avalanche photodiode.
Figure 3
Simulation (curve) and experiment results (data points) for secret rate (bit/pulse) vs the total distance in standard telecom fiber. (a) is fixed at 10km, while is selected at 40, 60, 80, and 90km. (b) is fixed at 0km, while is selected at 40, 60, 80, and 100km. The points (curves) in the figure indicate the experimental (simulation) results for (i)the 4-intensity method shown as blue diamonds (blue dashed line), where the same intensities and proportions for Alice and Bob are selected and optimized in the 4-intensity protocol [21, 28]; (ii)the method [14] shown as black dots (black dot-dash line); (iii)the 7-intensity method [34], shown in red squares (red solid line). As can be seen, for the 4-intensity methods, adding fibers improves the key rate in long distances, but it does not in short distances. In contrast, the 7-intensity method always achieves a substantially higher key rate than any of the other two methods, especially when channel asymmetry is high.
