Related papers: Effect of light injection on the security of practical quantum key distribution

Effect of light injection on the security of practical quantum key distribution

URL: http://arxiv.org/abs/2303.14683v2
Date: Tue, 2 Jan 2024 06:37:09 GMT
Title: Effect of light injection on the security of practical quantum key distribution
Authors: Liying Han, Yang Li, Hao Tan, Weiyang Zhang, Wenqi Cai, Juan Yin, Jigang Ren, Feihu Xu, Shengkai Liao, Chengzhi Peng
Abstract summary: Quantum key distribution (QKD) based on the fundamental laws of quantum physics can allow the distribution of secure keys between distant users. We find that optical modulators based on LiNbO3, including phase modulators and intensity modulators, are vulnerable to photorefractive effect caused by external light injection. We have experimentally demonstrated the influence of light injection on LiNbO3-based optical modulators and analyzed the security risks caused by the potential green light injection attack, along with the corresponding countermeasures.
Score: 15.80376879485642
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Quantum key distribution (QKD) based on the fundamental laws of quantum physics can allow the distribution of secure keys between distant users. However, the imperfections in realistic devices may lead to potential security risks, which must be accurately characterized and considered in practical security analysis. High-speed optical modulators, being as one of the core components of practical QKD systems, can be used to prepare the required quantum states. Here, we find that optical modulators based on LiNbO3, including phase modulators and intensity modulators, are vulnerable to photorefractive effect caused by external light injection. By changing the power of external light, eavesdroppers can control the intensities of the prepared states, posing a potential threat to the security of QKD. We have experimentally demonstrated the influence of light injection on LiNbO3-based optical modulators and analyzed the security risks caused by the potential green light injection attack, along with the corresponding countermeasures.

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