High key rate continuous-variable quantum key distribution using telecom optical components

New Journal of Physics Pub Date : 2024-01-05 DOI:10.1088/1367-2630/ad1b7e

Tao Wang, Peng Huang, Lang Li, Yingming Zhou, Guihua Zeng

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Abstract

Quantum key distribution (QKD) is one quantum technology that can provide secure encryption keys for data transmission. The secret key rate is a core performance indicator in QKD, which directly determines the transmission rate of enciphered data. Here, for the first time, we demonstrate a high-key-rate Gaussian-modulated continuous-variable QKD (CV-QKD) using telecom optical components. The framework of CV-QKD over these components is constructed. Specifically, the high-rate low-noise Gaussian modulation of coherent states is realized by a classical optical IQ modulator. High-baud low-intensity quantum signals are received by an integrated coherent receiver under the shot-noise limit. A series of digital signal processing algorithms are proposed to achieve accurate signal recovery and key distillation. The system can yield a high asymptotic secret key rate of 10.37 Mbps within 20 km standard telecom fiber, and the secure distance can exceed 100 km. This result confirms the feasibility of CV-QKD with state-of-the-art performance using telecom optical components. Besides, due to the ease of integrating these discrete components, it provides a high-performance and miniaturized QKD solution for the metropolitan quantum network.

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利用电信光学元件实现高密钥速率连续可变量子密钥分发

量子密钥分发（QKD）是一种能为数据传输提供安全加密密钥的量子技术。密钥速率是 QKD 的核心性能指标，它直接决定了加密数据的传输速率。在这里，我们首次展示了利用电信光学元件实现的高密钥率高斯调制连续可变 QKD（CV-QKD）。通过这些元件构建了 CV-QKD 框架。具体来说，相干态的高速率低噪声高斯调制由经典光学 IQ 调制器实现。高波特低强度量子信号由集成相干接收器在射噪限制下接收。为实现精确的信号恢复和密钥提炼，提出了一系列数字信号处理算法。该系统可在 20 千米标准电信光纤内实现 10.37 Mbps 的高渐近秘钥速率，安全距离可超过 100 千米。这一结果证实了利用电信光纤元件实现具有最先进性能的 CV-QKD 的可行性。此外，由于这些分立元件易于集成，它为城域量子网络提供了一种高性能、小型化的 QKD 解决方案。

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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New Journal of Physics

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