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Main Authors: Ruzhitskaya, Daria, Zhluktova, Irina, Ponosova, Anastasiya, Ushakov, Fedor, Zverev, Andrey, Tertyshnikova, Galina, Xing, Tianyi, Min'kov, Kirill, Trefilov, Daniil, Huang, Anqi, Kamynin, Vladimir, Tsvetkov, Vladimir, Makarov, Vadim
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.25620
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author Ruzhitskaya, Daria
Zhluktova, Irina
Ponosova, Anastasiya
Ushakov, Fedor
Zverev, Andrey
Tertyshnikova, Galina
Xing, Tianyi
Min'kov, Kirill
Trefilov, Daniil
Huang, Anqi
Kamynin, Vladimir
Tsvetkov, Vladimir
Makarov, Vadim
author_facet Ruzhitskaya, Daria
Zhluktova, Irina
Ponosova, Anastasiya
Ushakov, Fedor
Zverev, Andrey
Tertyshnikova, Galina
Xing, Tianyi
Min'kov, Kirill
Trefilov, Daniil
Huang, Anqi
Kamynin, Vladimir
Tsvetkov, Vladimir
Makarov, Vadim
contents The security of quantum key distribution (QKD) systems relies on the physical integrity of their components. While laser-damage attacks (LDAs) using high-power continuous-wave (cw) lasers have been well studied, the threat posed by pulsed lasers at alternative wavelengths remains underestimated. Here, we experimentally investigated the stability of four types of fiber-optic attenuators under exposure to sub-picosecond pulses at 1061 nm with average power reaching 1 W. Mechanical variable attenuators with blocking elements and fixed air-gap attenuators show resistance to this attack. MEMS-based variable attenuators exhibit increased attenuation or irreversible damage that causes a permanent reduction in attenuation of approximately 3.8 dB. For fixed attenuators with an absorption element, we demonstrate that initial pulsed irradiation significantly lowers the optical damage threshold of the components compared to direct cw attacks. The attenuation reduction achieved is up to 7 dB at a 1 W cw laser at 1550 nm. These results highlight the possibility of establishing a hidden side-channel for eavesdropping attacks and underscore the insufficiency of existing countermeasures against sophisticated LDA scenarios.
format Preprint
id arxiv_https___arxiv_org_abs_2604_25620
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Robustness of fiber-optic attenuators to 1061-nm sub-nanosecond pulsed laser radiation in quantum key distribution systems
Ruzhitskaya, Daria
Zhluktova, Irina
Ponosova, Anastasiya
Ushakov, Fedor
Zverev, Andrey
Tertyshnikova, Galina
Xing, Tianyi
Min'kov, Kirill
Trefilov, Daniil
Huang, Anqi
Kamynin, Vladimir
Tsvetkov, Vladimir
Makarov, Vadim
Quantum Physics
The security of quantum key distribution (QKD) systems relies on the physical integrity of their components. While laser-damage attacks (LDAs) using high-power continuous-wave (cw) lasers have been well studied, the threat posed by pulsed lasers at alternative wavelengths remains underestimated. Here, we experimentally investigated the stability of four types of fiber-optic attenuators under exposure to sub-picosecond pulses at 1061 nm with average power reaching 1 W. Mechanical variable attenuators with blocking elements and fixed air-gap attenuators show resistance to this attack. MEMS-based variable attenuators exhibit increased attenuation or irreversible damage that causes a permanent reduction in attenuation of approximately 3.8 dB. For fixed attenuators with an absorption element, we demonstrate that initial pulsed irradiation significantly lowers the optical damage threshold of the components compared to direct cw attacks. The attenuation reduction achieved is up to 7 dB at a 1 W cw laser at 1550 nm. These results highlight the possibility of establishing a hidden side-channel for eavesdropping attacks and underscore the insufficiency of existing countermeasures against sophisticated LDA scenarios.
title Robustness of fiber-optic attenuators to 1061-nm sub-nanosecond pulsed laser radiation in quantum key distribution systems
topic Quantum Physics
url https://arxiv.org/abs/2604.25620