Micius quantum experiments in space

IF 45.9 1区物理与天体物理 Q1 PHYSICS, MULTIDISCIPLINARY Reviews of Modern Physics Pub Date : 2022-07-06 DOI:10.1103/revmodphys.94.035001

Chao-Yang Lu, Yuan Cao, Cheng-Zhi Peng, Jian-Wei Pan

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Abstract

Quantum theory has been successfully validated in numerous laboratory experiments. But would such a theory, which effectively describes the behavior of microscopic physical systems and its predicted phenomena such as quantum entanglement, still be applicable on large length scales? From a practical perspective, how can quantum key distribution (where the security of establishing secret keys between distant parties is ensured by the laws of quantum mechanics) be made technologically useful on a global scale? Owing to photon loss in optical fibers and terrestrial free space, the achievable distance using direct transmission of single photons has been limited to a few hundred kilometers. A promising route to testing quantum physics over long distances and in the relativistic regimes, and thus realizing flexible global-scale quantum networks, is via the use of satellites and space-based technologies, where a significant advantage is that the photon loss and turbulence predominantly occurs in the lower

\sim 10 km

of the atmosphere, and most of the photons’ transmission path in space is virtually in vacuum, with almost zero absorption and decoherence. Progress in free-space quantum experiments, with a focus on the fast-developing Micius satellite–based quantum communications, is reviewed. The perspective of space-ground integrated quantum networks and fundamental quantum optics experiments in space conceivable with satellites are discussed.

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墨子号在太空进行量子实验

量子理论已经在许多实验室实验中得到了成功的验证。但是，这样一个有效地描述微观物理系统行为及其预测现象(如量子纠缠)的理论，是否仍然适用于大长度尺度?从实际的角度来看，如何使量子密钥分发(在遥远的各方之间建立密钥的安全性由量子力学定律确保)在全球范围内在技术上有用?由于光纤和地面自由空间中的光子损耗，使用单光子直接传输的可实现距离被限制在几百公里。在长距离和相对论体制中测试量子物理，从而实现灵活的全球尺度量子网络的一个有希望的途径是通过使用卫星和空间技术，其中一个显著的优势是光子损失和湍流主要发生在大气的较低~ 10公里处，并且大多数光子在空间中的传输路径实际上是在真空中，几乎没有吸收和退相干。综述了自由空间量子实验的进展，重点介绍了快速发展的墨子号卫星量子通信。讨论了空间-地面集成量子网络的发展前景和卫星可实现的空间量子光学基础实验。

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来源期刊

Reviews of Modern Physics 物理-物理：综合

CiteScore

76.20

自引率

0.70%

发文量

期刊介绍： Reviews of Modern Physics (RMP) stands as the world's foremost physics review journal and is the most extensively cited publication within the Physical Review collection. Authored by leading international researchers, RMP's comprehensive essays offer exceptional coverage of a topic, providing context and background for contemporary research trends. Since 1929, RMP has served as an unparalleled platform for authoritative review papers across all physics domains. The journal publishes two types of essays: Reviews and Colloquia. Review articles deliver the present state of a given topic, including historical context, a critical synthesis of research progress, and a summary of potential future developments.

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