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Auteurs principaux: Lu, Feng-Yu, Li, Jia-Xuan, Wang, Ze-Hao, Wang, Shuang, Yin, Zhen-Qiang, Navarrete, Alvaro, Curty, Marcos, Chen, Wei, He, De-Yong, Guo, Guang-Can, Han, Zheng-Fu
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2509.00438
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author Lu, Feng-Yu
Li, Jia-Xuan
Wang, Ze-Hao
Wang, Shuang
Yin, Zhen-Qiang
Navarrete, Alvaro
Curty, Marcos
Chen, Wei
He, De-Yong
Guo, Guang-Can
Han, Zheng-Fu
author_facet Lu, Feng-Yu
Li, Jia-Xuan
Wang, Ze-Hao
Wang, Shuang
Yin, Zhen-Qiang
Navarrete, Alvaro
Curty, Marcos
Chen, Wei
He, De-Yong
Guo, Guang-Can
Han, Zheng-Fu
contents Implementation security, higher generation rate, and lower cost are primary missions in the domain of quantum key distributions in recent years. However, simultaneously achieving robust security, high speed, and low cost often resembles an ``impossible triangle''. This is largely because the modulation system imposes a strict bandwidth limitation. Pushing a low-cost modulator to a high repetition frequency inevitably introduces correlations and misalignment, which can create security loopholes. Conversely, operating at a conservative rate fails to exploit the system's potential, while adopting ultra-high-bandwidth components is often expensive for practical implementation, forcing a perpetual trade-off among implementation security, key rate, and cost. In this work, we propose a comprehensive countermeasure to overcome this modulation bandwidth bottleneck. We present a protocol specifically designed to address the security loopholes arising from modulation imperfections, ensuring security even in overclocked modulation systems. Furthermore, we develop two practical techniques to characterize and mitigate the detrimental correlations. Our experimental setup demonstrates that the proposed method achieves the lowest correlated deviation reported in similar studies, while maintaining a high secret key rate using a bandwidth-limited modulation system. By simultaneously enhancing security, performance, and practicality, this work releases QKD systems from the traditional performance-cost trade-off in the near term, paving the way for widespread deployment. In the long run, this work can be readily integrated with high-bandwidth components to further push the boundaries of system performance.
format Preprint
id arxiv_https___arxiv_org_abs_2509_00438
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Fault-Tolerant Quantum Key Distribution: Enabling Overclocked Modulation
Lu, Feng-Yu
Li, Jia-Xuan
Wang, Ze-Hao
Wang, Shuang
Yin, Zhen-Qiang
Navarrete, Alvaro
Curty, Marcos
Chen, Wei
He, De-Yong
Guo, Guang-Can
Han, Zheng-Fu
Quantum Physics
Implementation security, higher generation rate, and lower cost are primary missions in the domain of quantum key distributions in recent years. However, simultaneously achieving robust security, high speed, and low cost often resembles an ``impossible triangle''. This is largely because the modulation system imposes a strict bandwidth limitation. Pushing a low-cost modulator to a high repetition frequency inevitably introduces correlations and misalignment, which can create security loopholes. Conversely, operating at a conservative rate fails to exploit the system's potential, while adopting ultra-high-bandwidth components is often expensive for practical implementation, forcing a perpetual trade-off among implementation security, key rate, and cost. In this work, we propose a comprehensive countermeasure to overcome this modulation bandwidth bottleneck. We present a protocol specifically designed to address the security loopholes arising from modulation imperfections, ensuring security even in overclocked modulation systems. Furthermore, we develop two practical techniques to characterize and mitigate the detrimental correlations. Our experimental setup demonstrates that the proposed method achieves the lowest correlated deviation reported in similar studies, while maintaining a high secret key rate using a bandwidth-limited modulation system. By simultaneously enhancing security, performance, and practicality, this work releases QKD systems from the traditional performance-cost trade-off in the near term, paving the way for widespread deployment. In the long run, this work can be readily integrated with high-bandwidth components to further push the boundaries of system performance.
title Fault-Tolerant Quantum Key Distribution: Enabling Overclocked Modulation
topic Quantum Physics
url https://arxiv.org/abs/2509.00438