Optimized protocol for twin-field quantum key distribution.

Twin-field quantum key distribution (TF-QKD) and its variant protocols are highly attractive due to the advantage of overcoming the rate-loss limit for secret key rates of point-to-point QKD protocols. For variations of TF-QKD, the key point to ensure security is switching randomly between a code mode and a test mode. Among all TF-QKD protocols, their code modes are very different, e.g. modulating continuous phases, modulating only two opposite phases, and sending or not sending signal pulses. Here we show that, by discretizing the number of global phases in the code mode, we can give a unified view on the first two types of TF-QKD protocols, and demonstrate that increasing the number of discrete phases extends the achievable distance, and as a trade-off, lowers the secret key rate at short distances due to the phase post-selection. Quantum key distribution is a method to enable secure communication between two parties and prevent an eavesdropper from stealing information. Here, the authors use twin-field quantum key distribution combined with discrete phase randomisation to improve on the distance at which secure communication can be achieved. [ABSTRACT FROM AUTHOR]