Direct and full-scale experimental verifications towards ground–satellite quantum key distribution

Wang, Yunlong; Yang, Bin; Liao, Sheng-Kai; Zhang, Liang; Shen, Qi; Hu, Xiaofang; Wu, Jincai; Yang, Shiji; Jiang, Hao; Tang, Yan-Lin; Zhong, Bo; Liang, H.; Liu, Weiyue; Hu, Yihua; Huang, Yongmei; Qi, Bo; Ren, Ji-Gang; Pan, Ge-Sheng; Yin, Juan; Jia, Jianjun; Chen, Yu-Ao; Chen, Kai; Peng, Cheng-Zhi; Pan, Jian-Wei

doi:10.1038/nphoton.2013.89

Cited by 264 publications

(160 citation statements)

References 30 publications

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“…Since then, there have been significant efforts, and free space QKD and quantum teleportation over a long distance of 144 km were demonstrated [38,39]. Recently, free space QKD experiments were extended to airborne-to-ground [40], and a moving platform consisting of a vibrating turntable and a balloon [41]. In these works, the receiver was located at a fixed place, simulating a downlink from satellite to ground.…”

Section: Qkd and Physical Layer Cryptographymentioning

confidence: 99%

Quantum networks: where should we be heading?

Sasaki

2017

Quantum Sci. Technol.

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Quantum key distribution network has become a reality in practical environment. Quantum repeaters have been explored in various physical systems and their combinations. For practical use of them, these new paradigms must be combined with existing or emerging infrastructures of communication and security systems. In this article, we discussed how quantum network can be combined with modern cryptographic technologies in fibre network and with emerging mobile terminals in wireless network, creating new solutions for the future cryptographic and communication systems. Our discussions are summarised in a roadmap.

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Section: Qkd and Physical Layer Cryptographymentioning

confidence: 99%

Quantum networks: where should we be heading?

Sasaki

2017

Quantum Sci. Technol.

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“…To make this approximation valid, the detection efficiency must not be dependent on the specific coincidence pattern. Therefore, we applied a discard rule with keep probabilities 1, 0.625, 0.536, 0.625, and 1 for the five possible outcomes, (4,0), (3,1), (2,2), (1,3), and (0,4), respectively [47].…”

Section: Photon-number Detectionmentioning

confidence: 99%

“…The most widely used method for this purpose is quantum process tomography (QPT)-in which a mathematical description of a quantum process is reconstructed by estimating the probabilities of outcomes for a selection of probe states and measurement settings. For example for quantum technology, QPT is used to characterize multi-qubit processors [1] and quantum communication channels [2]; across quantum physics, QPT of some form is often the first experimental investigation of a new physical process-for example, recent research into coherent transport in biological mechanisms [3]. QPT has been demonstrated in a variety of physical systems, including ion traps [4], nuclear magnetic resonance [5], superconducting circuits [6] and nitrogen-vacancy color centers [7].…”

Section: Introductionmentioning

confidence: 99%

Quantum-enhanced tomography of unitary processes

Zhou¹,

Cable²,

Whittaker³

et al. 2015

Optica

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This is the final published version of the article (version of record). It first appeared online via OSA at https://www.osapublishing.org/optica/abstract.cfm?uri=optica-2-6-510. Please refer to any applicable terms of use of the publisher. University of Bristol -Explore Bristol Research General rightsThis document is made available in accordance with publisher policies. Please cite only the published version using the reference above. A fundamental task in photonics is to characterize an unknown optical process, defined by properties such as birefringence, spectral response, thickness and flatness. Among many ways to achieve this, single-photon probes can be used in a method called quantum process tomography (QPT). However, the precision of QPT is limited by unavoidable shot noise when implemented using single-photon probes or laser light. In situations where measurement resources are limited, for example, where the process (sample) to be probed is very delicate such that the exposure to light has a detrimental effect on the sample, it becomes essential to overcome this precision limit.Here we devise a scheme for process tomography with a quantum-enhanced precision by drawing upon techniques from quantum metrology. We implement a proof-of-principle experiment to demonstrate this scheme-four-photon quantum states are used to probe an unknown arbitrary unitary process realized with an arbitrary polarization rotation. Our results show a substantial reduction of statistical fluctuations compared to traditional QPT methods-in the ideal case, one four-photon probe state yields the same amount of statistical information as twelve single probe photons.

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“…In this case a single half wave plate is sufficient to reestablish the common reference frame. In [120], an otherwise similar QKD experiment linking to a hot-air balloon is presented which is, however, realized without any polarization compensation. This is possible as the vertical direction is always well defined for the balloon.…”

Section: Secure Key Ratementioning

confidence: 99%