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Bibliographic Details
Main Author: Miller, Alexander
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2505.06532
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author Miller, Alexander
author_facet Miller, Alexander
contents The decoy-state BB84 protocol for quantum key distribution (QKD) is used on Micius, the world's first satellite for quantum communications. The method of decoy states can detect photon-number-splitting eavesdropping and thus enables, in theory, secure QKD using weak coherent pulses over long distances with high channel loss inherent in satellite communication systems. However, it is widely known that realistic QKD devices can be vulnerable to various types of side-channel attacks that rely on flaws in experimental implementation. In most free-space QKD systems, including that on board Micius, multiple semiconductor lasers with passive optics are utilized to randomly generate polarization states. Optical pulses from independent laser diodes can to some extent differ in their temporal, spectral, and/or spatial distribution, and the quantum states can thus be distinguishable. Such distinguishability of photons in additional non-operational degrees of freedom compromises unconditional security of QKD since an eavesdropper can exploit this loophole to improve their attack strategy. The author carried out a thorough analysis of the experimental data obtained during multiple communication sessions between Micius and one of the ground stations designed specifically for it. Relative time delays between all the eight laser diodes on board have been found. The typical desynchronization between the lasers exceeds 100 ps, which is comparable with their pulse duration of 200 ps. The largest time delay was observed between signal and decoy states for vertically polarized photons and is about 300 ps. With such mismatch in timing, a potential attacker using as perfect equipment as possible unless it violates the laws of physics was shown to be capable of distinguishing decoy states from signal ones in at least 98.7% of cases.
format Preprint
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institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Micius, the world's first quantum communication satellite, was hackable
Miller, Alexander
Quantum Physics
The decoy-state BB84 protocol for quantum key distribution (QKD) is used on Micius, the world's first satellite for quantum communications. The method of decoy states can detect photon-number-splitting eavesdropping and thus enables, in theory, secure QKD using weak coherent pulses over long distances with high channel loss inherent in satellite communication systems. However, it is widely known that realistic QKD devices can be vulnerable to various types of side-channel attacks that rely on flaws in experimental implementation. In most free-space QKD systems, including that on board Micius, multiple semiconductor lasers with passive optics are utilized to randomly generate polarization states. Optical pulses from independent laser diodes can to some extent differ in their temporal, spectral, and/or spatial distribution, and the quantum states can thus be distinguishable. Such distinguishability of photons in additional non-operational degrees of freedom compromises unconditional security of QKD since an eavesdropper can exploit this loophole to improve their attack strategy. The author carried out a thorough analysis of the experimental data obtained during multiple communication sessions between Micius and one of the ground stations designed specifically for it. Relative time delays between all the eight laser diodes on board have been found. The typical desynchronization between the lasers exceeds 100 ps, which is comparable with their pulse duration of 200 ps. The largest time delay was observed between signal and decoy states for vertically polarized photons and is about 300 ps. With such mismatch in timing, a potential attacker using as perfect equipment as possible unless it violates the laws of physics was shown to be capable of distinguishing decoy states from signal ones in at least 98.7% of cases.
title Micius, the world's first quantum communication satellite, was hackable
topic Quantum Physics
url https://arxiv.org/abs/2505.06532