Elements of satellite quantum network

International Conference on Micro- and Nano-Electronics Pub Date : 2022-01-30 DOI:10.1117/12.2624443

V. Kurochkin, A. Khmelev, V. Mayboroda, R. M. Bakhshaliev, A. V. Duplinsky, Y. Kurochkin

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引用次数: 1

Abstract

Long-distance quantum key distribution (QKD) is a critical component of a quantum network. When network users are within a city, they often use existing telecommunication fiber-optic networks. This method is problematic for QKD on a large scale between cities and countries. Direct connecting of distant consumers with quantum single-photon lines is not possible, because optical fiber involves attenuation. This problem is addressed by constructing a large number of trusted intermediate nodes, but there are concerns with the reliability of each node. To increase the quantum network's dependability, a method of building a satellite quantum network is actively developing. The only one trusted satellite node is required for satellite QKD between any two points on the Earth's surface. Furthermore, a satellite quantum link can also be utilized to add another communication channel in the existing fiber-optic networks that are thousands of kilometers apart. We describe the creation of ground infrastructure elements for receiving single photons in various polarization quantum states from satellites. Ground-based receiving nodes are based on two telescopes with an aperture of 1.2 m and 0.6 m located in remote cities.

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卫星量子网络的要素

远程量子密钥分发(QKD)是量子网络的关键组成部分。当网络用户在城市内时，他们通常使用现有的电信光纤网络。这种方法在城市和国家之间的大规模QKD中存在问题。用量子单光子线直接连接远程用户是不可能的，因为光纤涉及衰减。这个问题可以通过构造大量可信的中间节点来解决，但是需要考虑每个节点的可靠性。为了提高量子网络的可靠性，一种构建卫星量子网络的方法正在积极发展。地球表面任意两点之间的卫星QKD只需要一个可信的卫星节点。此外，卫星量子链路还可以用于在相距数千公里的现有光纤网络中增加另一个通信通道。我们描述了用于从卫星接收不同偏振量子态的单光子的地面基础设施元素的创建。地面接收节点基于位于偏远城市的两个口径分别为1.2米和0.6米的望远镜。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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International Conference on Micro- and Nano-Electronics

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