Surpassing the repeaterless bound with a photon-number encoded measurement-device-independent quantum key distribution protocol

Decoherence is detrimental to quantum key distribution (QKD) over large distances. One of the proposed solutions is to use quantum repeaters, which divide the total distance between the users into smaller segments to minimise the effects of the losses in the channel. Here we introduce a measurement-device-independent protocol which uses high-dimensional states prepared by two distant trusted parties and a coherent total photon number detection for the entanglement swapping measurement at the repeater station. We present an experimentally feasible protocol that can be implemented with current technology as the required states reduce down to the single-photon level over large distances. This protocol outperforms the existing measurement-device-independent and twin-field QKD protocols by achieving better key rates in general and higher transmission distance in total when experimental imperfections are considered. It also surpasses the fundamental limit of the repeaterless bound at a much shorter transmission distance in comparison to the existing TF-QKD protocols.

Automated summary

Decoherence is a problem for quantum key distribution (QKD) over long distances. This paper proposes the use of quantum repeaters to minimize the effects of losses in the channel by dividing the total distance between users into smaller segments. A measurement-device-independent protocol is introduced, which uses high-dimensional states prepared by two trusted parties and a coherent total photon number detection for entanglement swapping at the repeater station. The experimentally feasible protocol achieves better key rates and longer transmission distance compared to existing protocols, surpassing the fundamental limit of repeaterless bound even at a shorter distance than existing TF-QKD protocols.