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Quantum hacking perceiving for quantum key distribution using temporal ghost imaging

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 Added by Fang-Xiang Wang
 Publication date 2020
  fields Physics
and research's language is English




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Quantum key distribution (QKD) can generate secure key bits between remote users with quantum mechanics. However, the gap between the theoretical model and practical realizations gives eavesdroppers opportunities to intercept secret key. The most insidious attacks, known as quantum hacking, are the ones with no significant discrepancy of the measurement results using side-channel loopholes of QKD systems. Depicting full-time-scale characteristics of the quantum signals, the quantum channel, and the QKD system can provide legitimate users extra capabilities to defeat malicious attacks. For the first time, we propose the method exploring temporal ghost imaging (TGI) scheme to perceive quantum hacking with temporal fingerprints and experimentally verify its validity. The scheme presents a common approach to promote QKDs practical security from a new perspective of signals and systems.



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123 - Zhihao Wu , Anqi Huang , Huan Chen 2020
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