Your search keyword '"Jian-Yu Guan"' showing total 10 results

1. Experimental Passive Round-Robin Differential Phase-Shift Quantum Key Distribution.

Author

Jian-Yu Guan, Zhu Cao, Yang Liu, Guo-Liang Shen-Tu, Pelc, Jason S., Fejer, M. M., Cheng-Zhi Peng, Xiongfeng Ma, Qiang Zhang, and Jian-Wei Pan

Subjects

*BIT error rate, *DATA transmission systems, *TOURNAMENTS (Graph theory), *ENTROPY, *PHOTON counting

Abstract

In quantum key distribution (QKD), the bit error rate is used to estimate the information leakage and hence determines the amount of privacy amplification--making the final key private by shortening the key. In general, there exists a threshold of the error rate for each scheme, above which no secure key can be generated. This threshold puts a restriction on the environment noises. For example, a widely used QKD protocol, the Bennett-Brassard protocol, cannot tolerate error rates beyond 25%. A new protocol, round-robin differential phase-shifted (RRDPS) QKD, essentially removes this restriction and can in principle tolerate more environment disturbance. Here, we propose and experimentally demonstrate a passive RRDPS QKD scheme. In particular, our 500 MHz passive RRDPS QKD system is able to generate a secure key over 50 km with a bit error rate as high as 29%. This scheme should find its applications in noisy environment conditions. [ABSTRACT FROM AUTHOR]

Published

2015

2. Observation of Quantum Fingerprinting Beating the Classical Limit.

Author

Jian-Yu Guan, Feihu Xu, Hua-Lei Yin, Yuan Li, Wei-Jun Zhang, Si-Jing Chen, Xiao-Yan Yang, Li Li, Li-Xing You, Teng-Yun Chen, Zhen Wang, Qiang Zhang, and Jian-Wei Pan

Subjects

*QUANTUM communication, *QUANTUM mechanics, *HUMAN fingerprints

Abstract

Quantum communication has historically been at the forefront of advancements, from fundamental tests of quantum physics to utilizing the quantum-mechanical properties of physical systems for practical applications. In the field of communication complexity, quantum communication allows the advantage of an exponential reduction in the transmitted information over classical communication to accomplish distributed computational tasks. However, to date, demonstrating this advantage in a practical setting continues to be a central challenge. Here, we report a proof-of-principle experimental demonstration of a quantum fingerprinting protocol that for the first time surpasses the ultimate classical limit to transmitted information. Ultralow noise superconducting single-photon detectors and a stable fiber-based Sagnac interferometer are used to implement a quantum fingerprinting system that is capable of transmitting less information than the classical proven lower bound over 20 km standard telecom fiber for input sizes of up to 2 Gbits. The results pave the way for experimentally exploring the advanced features of quantum communication and open a new window of opportunity for research in communication complexity and testing the foundations of physics. [ABSTRACT FROM AUTHOR]

Published

2016

3. Experimental measurement-device-independent quantum random-number generation.

Author

You-Qi Nie, Jian-Yu Guan, Hongyi Zhou, Qiang Zhang, Xiongfeng Ma, Jun Zhang, and Jian-Wei Pan

Subjects

*QUANTUM numbers, *ENTROPY, *QUANTUM states

Abstract

The randomness from a quantum random-number generator (QRNG) relies on the accurate characterization of its devices. However, device imperfections and inaccurate characterizations can result in wrong entropy estimation and bias in practice, which highly affects the genuine randomness generation and may even induce the disappearance of quantum randomness in an extreme case. Here we experimentally demonstrate a measurement-device-independent (MDI) QRNG based on time-bin encoding to achieve certified quantum randomness even when the measurement devices are uncharacterized and untrusted. The MDI-QRNG is randomly switched between the regular randomness generation mode and a test mode, in which four quantum states are randomly prepared to perform measurement tomography in real time. With a clock rate of 25 MHz, the MDI-QRNG generates a final random bit rate of 5.7 kbps. Such implementation with an all-fiber setup provides an approach to construct a fully integrated MDI-QRNG with trusted but error-prone devices in practice. [ABSTRACT FROM AUTHOR]

Published

2016

4. Quantum Coherence Witness with Untrusted Measurement Devices.

Author

You-Qi Nie, Hongyi Zhou, Jian-Yu Guan, Qiang Zhang, Xiongfeng Ma, Jun Zhang, and Jian-Wei Pan

Subjects

*QUANTUM coherence, *QUANTUM information science, *WITNESSES, *INFORMATION resources

Abstract

Coherence is a fundamental resource in quantum information processing, which can be certified by a coherence witness. Due to the imperfection of measurement devices, a conventional coherence witness may lead to fallacious results. We show that the conventional witness could mistake an incoherent state as a state with coherence due to the inaccurate settings of measurement bases. In order to make the witness result reliable, we propose a measurement-device-independent coherence witness scheme without any assumptions on the measurement settings. We introduce the decoy-state method to significantly increase the capability of recognizing states with coherence. Furthermore, we experimentally demonstrate the scheme in a time-bin encoding optical system. [ABSTRACT FROM AUTHOR]

Published

2019

5. Measurement-Device-Independent Quantum Key Distribution over 200 km.

Author

Yan-Lin Tang, Hua-Lei Yin, Si-Jing Chen, Yang Liu, Wei-Jun Zhang, Xiao Jiang, Lu Zhang, Jian Wang, Li-Xing You, Jian-Yu Guan, Dong-Xu Yang, Zhen Wang, Hao Liang, Zhen Zhang, Nan Zhou, Xiongfeng Ma, Teng-Yun Chen, Qiang Zhang, and Jian-Wei Pan

Subjects

*QUANTUM theory, *QUANTUM mechanics, *QUANTUM information science, *QUANTUM information theory, *NANOWIRE optical sensors, *SINGLE photon generation

Abstract

Measurement-device-independent quantum key distribution (MDIQKD) protocol is immune to all attacks on detection and guarantees the information-theoretical security even with imperfect single-photon detectors. Recently, several proof-of-principle demonstrations of MDIQKD have been achieved. Those experiments, although novel, are implemented through limited distance with a key rate less than 0.1 bit/s. Here, by developing a 75 MHz clock rate fully automatic and highly stable system and superconducting nanowire single-photon detectors with detection efficiencies of more than 40%, we extend the secure transmission distance of MDIQKD to 200 km and achieve a secure key rate 3 orders of magnitude higher. These results pave the way towards a quantum network with measurement-device-independent security. [ABSTRACT FROM AUTHOR]

Published

2014

6. Sending-or-Not-Sending with Independent Lasers: Secure Twin-Field Quantum Key Distribution over 509 km.

Author

Jiu-Peng Chen, Chi Zhang, Yang Liu, Cong Jiang, Weijun Zhang, Xiao-Long Hu, Jian-Yu Guan, Zong-Wen Yu, Hai Xu, Jin Lin, Ming-Jun Li, Hao Chen, Hao Li, Lixing You, Zhen Wang, Xiang-Bin Wang, Qiang Zhang, and Jian-Wei Pan

Subjects

*OPTICAL losses, *OPTICAL fibers, *LASERS, *QUANTUM communication

Abstract

Twin-field (TF) quantum key distribution (QKD) promises high key rates over long distances to beat the rate-distance limit. Here, applying the sending-or-not-sending TF QKD protocol, we experimentally demonstrate a secure key distribution that breaks the absolute key-rate limit of repeaterless QKD over a 509-km-long ultralow loss optical fiber. Two independent lasers are used as sources with remote-frequency-locking technique over the 500-km fiber distance. Practical optical fibers are used as the optical path with appropriate noise filtering; and finite-key effects are considered in the key-rate analysis. The secure key rate obtained at 509 km is more than seven times higher than the relative bound of repeaterless QKD for the same detection loss. The achieved secure key rate is also higher than that of a traditional QKD protocol running with a perfect repeaterless QKD device, even for an infinite number of sent pulses. Our result shows that the protocol and technologies applied in this experiment enable TF QKD to achieve a high secure key rate over a long distribution distance, and is therefore practically useful for field implementation of intercity QKD. [ABSTRACT FROM AUTHOR]

Published

2020

7. Color Erasure Detectors Enable Chromatic Interferometry.

Author

Luo-Yuan Qu, Cotler, Jordan, Fei Ma, Jian-Yu Guan, Ming-Yang Zheng, Xiuping Xie, Yu-Ao Chen, Qiang Zhang, Wilczek, Frank, and Jian-Wei Pan

Subjects

*DETECTORS, *QUANTUM entanglement, *PHOTONS, *QUANTUM networks (Optics), *ASTRONOMY, *INTERFEROMETRY, *MICROSCOPY

Abstract

By engineering and manipulating quantum entanglement between incoming photons and experimental apparatus, we construct single-photon detectors which cannot distinguish between photons of very different wavelengths. These color-erasure detectors enable a new kind of intensity interferometry, with potential applications in microscopy and astronomy. We demonstrate chromatic interferometry experimentally, observing robust interference using both coherent and incoherent photon sources. [ABSTRACT FROM AUTHOR]

Published

2019

8. Experimental Twin-Field Quantum Key Distribution through Sending or Not Sending.

Author

Yang Liu, Zong-Wen Yu, Weijun Zhang, Jian-Yu Guan, Jiu-Peng Chen, Chi Zhang, Xiao-Long Hu, Hao Li, Cong Jiang, Jin Lin, Teng-Yun Chen, Lixing You, Zhen Wang, Xiang-Bin Wang, Qiang Zhang, and Jian-Wei Pan

Subjects

*PHOTON detectors, *LASER ultrasonics, *SQUARE root, *FIBER lasers

Abstract

Channel loss seems to be the most severe limitation on the practical application of long distance quantum key distribution. The idea of twin-field quantum key distribution can improve the key rate from the linear scale of channel loss in the traditional decoy-state method to the square root scale of the channel transmittance. However, the technical demands are rather tough because they require single photon level interference of two remote independent lasers. Here, we adopt the technology developed in the frequency and time transfer to lock two independent laser wavelengths and utilize additional phase reference light to estimate and compensate the fiber fluctuation. Further, with a single photon detector with a high detection rate, we demonstrate twin field quantum key distribution through the sending-or-not-sending protocol with a realistic phase drift over 300 km optical fiber spools. We calculate the secure key rates with the finite size effect. The secure key rate at 300 km (1.96 × 10-6) is higher than that of the repeaterless secret key capacity (8.64 × 10-7). [ABSTRACT FROM AUTHOR]

Published

2019

9. Publisher's Note: Measurement-Device-Independent Quantum Key Distribution over 200 km.

Author

Yan-Lin Tang, Hua-Lei Yin, Si-Jing Chen, Yang Liu, Wei-Jun Zhang, Xiao Jiang, Lu Zhang, Jian Wang, Li-Xing You, Jian-Yu Guan, Dong-Xu Yang, Zhen Wang, Hao Liang, Zhen Zhang, Nan Zhou, Xiongfeng Ma, Teng-Yun Chen, Qiang Zhang, and Jian-Wei Pan

Subjects

*QUANTUM theory, *THERMODYNAMICS

Abstract

A correction to the article "Measurement-Device-Independent Quantum Key Distribution over 200 km," published in a 2014 issue is presented.

Published

2015

10. Experimental round-robin differential phase-shift quantum key distribution.

Author

Yu-Huai Li, Yuan Cao, Hui Dai, Jin Lin, Zhen Zhang, Wei Chen, Yu Xu, Jian-Yu Guan, Sheng-Kai Liao, Juan Yin, Qiang Zhang, Xiongfeng Ma, Cheng-Zhi Peng, and Jian-Wei Pan

Subjects

*TELECOMMUNICATION security, *DIFFERENTIAL phase shift keying, *BIT error rate

Abstract

In conventional quantum key distribution (QKD) protocols, security is guaranteed by estimating the amount of leaked information. Such estimation tends to overrate, leading to a fundamental threshold of the bit error rate, which becomes a bottleneck of practical QKD development. This bottleneck is broken through by the recent work of round-robin differential phase-shift (RRDPS) protocol, which eliminates the fundamental threshold of the bit error rate. The key challenge for the implementation of the RRDPS scheme lies in the realization of a variable-delay Mach-Zehnder interferometer, which requires active and random choice of many delays. By designing an optical system with multiple switches and employing an active phase stabilization technology, we successfully construct a variable-delay interferometer with 127 actively selectable delays. With this measurement, we experimentally demonstrate the RRDPS protocol and obtain a final key rate of 15.54 bps with a total loss of 18 dB and an error rate of 8.9%. [ABSTRACT FROM AUTHOR]

Published

2016