Strong pulse illumination hacks self-differencing avalanche photodiode detectors in a high-speed quantum key distribution system

• URL: http://arxiv.org/abs/2205.04177v1
• Date: Mon, 9 May 2022 10:40:46 GMT
• Title: Strong pulse illumination hacks self-differencing avalanche photodiode detectors in a high-speed quantum key distribution system
• Authors: Binwu Gao, Zhihai Wu, Weixu Shi, Yingwen Liu, Dongyang Wang, Chunlin Yu, Anqi Huang, Junjie Wu
• Abstract summary: We investigate the loopholes of self-differencing(SD) avalanche photodiode(APD) detector. We demonstrate experimental testing of SD APD detector under strong pulse illumination attack. This attack presents blinding stability and helps an eavesdropper to learn the secret key without introducing extra QBER.
• Score: 3.5097098058555787
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: Implementation of high-speed quantum key distribution~(QKD) has become one of the major focus in the field, which produces high key-generation rate for applications. To achieve high-speed QKD, tailored techniques are developed and employed to quickly generate and detect quantum states. However, these techniques may introduce unique loopholes to compromise the security of QKD systems. In this paper, we investigate the loopholes of self-differencing~(SD) avalanche photodiode~(APD) detector, typically used for high-speed detection in a QKD system, and demonstrate experimental testing of SD APD detector under strong pulse illumination attack. This attack presents blinding stability and helps an eavesdropper to learn the secret key without introducing extra QBER. Based on this testing, we propose a set of criteria for protecting SD APD detectors from the strong pulse illumination attack.

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