Hefei National Laboratory for Physical Sciences at the Microscale and Department of Modern Physics, University of Science and Technology of China, Hefei, China.
Shanghai Branch, CAS Center for Excellence in Quantum Information and Quantum Physics, University of Science and Technology of China, Shanghai, China.
Nature. 2020 Jun;582(7813):501-505. doi: 10.1038/s41586-020-2401-y. Epub 2020 Jun 15.
Quantum key distribution (QKD) is a theoretically secure way of sharing secret keys between remote users. It has been demonstrated in a laboratory over a coiled optical fibre up to 404 kilometres long. In the field, point-to-point QKD has been achieved from a satellite to a ground station up to 1,200 kilometres away. However, real-world QKD-based cryptography targets physically separated users on the Earth, for which the maximum distance has been about 100 kilometres. The use of trusted relays can extend these distances from across a typical metropolitan area to intercity and even intercontinental distances. However, relays pose security risks, which can be avoided by using entanglement-based QKD, which has inherent source-independent security. Long-distance entanglement distribution can be realized using quantum repeaters, but the related technology is still immature for practical implementations. The obvious alternative for extending the range of quantum communication without compromising its security is satellite-based QKD, but so far satellite-based entanglement distribution has not been efficient enough to support QKD. Here we demonstrate entanglement-based QKD between two ground stations separated by 1,120 kilometres at a finite secret-key rate of 0.12 bits per second, without the need for trusted relays. Entangled photon pairs were distributed via two bidirectional downlinks from the Micius satellite to two ground observatories in Delingha and Nanshan in China. The development of a high-efficiency telescope and follow-up optics crucially improved the link efficiency. The generated keys are secure for realistic devices, because our ground receivers were carefully designed to guarantee fair sampling and immunity to all known side channels. Our method not only increases the secure distance on the ground tenfold but also increases the practical security of QKD to an unprecedented level.
量子密钥分发(QKD)是一种在远程用户之间共享密钥的理论上安全的方法。它已经在实验室中通过缠绕的光纤进行了演示,最长距离达到 404 公里。在现场,点对点 QKD 已经从卫星到地面站实现,距离可达 1200 公里。然而,基于实际 QKD 的加密技术针对的是地球上物理上分离的用户,其最大距离约为 100 公里。使用可信中继器可以将这些距离从典型的城市区域扩展到城市间甚至洲际距离。然而,中继器会带来安全风险,而使用基于纠缠的 QKD 可以避免这些风险,因为它具有固有的源独立安全性。长距离纠缠分发可以通过量子中继器来实现,但相关技术对于实际应用来说仍然不成熟。在不影响安全性的情况下扩展量子通信范围的明显替代方案是基于卫星的 QKD,但到目前为止,基于卫星的纠缠分发还不够高效,无法支持 QKD。在这里,我们演示了两个地面站之间的基于纠缠的 QKD,距离为 1120 公里,有限的秘密密钥率为 0.12 位/秒,无需可信中继器。纠缠光子对通过从 Micius 卫星到中国德令哈和南山两个地面观测站的两个双向下行链路分发。高效望远镜和后续光学器件的发展极大地提高了链路效率。生成的密钥对于实际设备是安全的,因为我们的地面接收器经过精心设计,可确保公平采样并对所有已知的侧信道免疫。我们的方法不仅将地面上的安全距离增加了十倍,而且还将 QKD 的实际安全性提高到了前所未有的水平。
