Discrete-phase-randomized twin-field quantum key distribution with advantage distillation

The twin-field quantum key distribution (TF-QKD) protocol and its variants provide promising solutions to long-distance information-theoretic-secure communication, which can surpass the fundamental rate-loss bound without quantum repeaters. Different from other variants, the discrete-phase-randomized TF-QKD variant only needs to modulate weak coherent sources with random discrete phases, which avoids the necessity of modulating continuously randomized phases and can be implemented with current technology. However, the discrete-phase-randomized variant compromises the performance of TF-QKD under high channel losses and error rates. To overcome this dilemma, we propose to adopt the advantage distillation method to improve the performance of discrete-phase-randomized TF-QKD, and analyze its security in the asymptotic case. Without changing the optical hardware of TF-QKD systems, the proposed scheme can improve the secret key rate under high channel losses and error rates, and extend the tolerable channel loss as well.