Unconditional security of the BB84 quantum key distribution protocol has been proved by exploiting the fundamental laws of quantum mechanics, but the practical quantum key distribution system maybe hacked by considering the imperfect state preparation and measurement respectively. Until now, different attacking schemes have been proposed by utilizing imperfect devices, but the general security analysis model against all of the practical attacking schemes has not been proposed. Here, we demonstrate that the general practical attacking schemes can be divided into the Trojan horse attack, strong randomness attack and weak randomness attack respectively. We prove security of BB84 protocol under randomness attacking models, and these results can be applied to guarantee the security of the practical quantum key distribution system.
Avalanche photodiode based single photon detectors, as crucial and practical components, are widely used in quantum key distribution (QKD) systems. For effective detection, most of these SPDs are operated in the gated mode, in which the gate is added to obtain high avalanche gain, and is removed to quench the avalanche. The avalanche transition region (ATR) is a certain existence in the process of adding and removing the gate. We first experimentally investigate the characteristic of the ATR, including in the commercial SPD and high-speed SPD, and then propose an ATR attack to control the detector. In the experiment of hacking the plug-and-play QKD system, Eve only introduces less than 0.5 % quantum bit error rate, and almost leaves no traces of her presence including the photocurrent and afterpulse probability. We finally give possible countermeasures against this attack.
Sine-wave gating method is widely used in high-speed single photon detection (SPD) but shows extra afterpulse probability compared with the self-differencing technique. Here, we demonstrate that most extra afterpulses of the sine-wave gating SPD come from successive avalanche signals and distortion of electrical filters and also propose an effective method by removing the wider filtered avalanche signals to reduce the afterpulse probability. At 1 GHz gating frequency, the ultralow afterpulse probability is characterized as 1.0% and 0.54% for a photon detection efficiency of 20.7% and 10.9%, respectively.
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