Abstract
Two time-reversal quantum key distribution (QKD) schemes are the quantum entanglement based device-independent (DI)-QKD and measurement-device-independent (MDI)-QKD. The recently proposed twin field (TF)-QKD, also known as phase-matching (PM)-QKD, has improved the key rate bound from O(η) to O(sqrt{{boldsymbol{eta }}}) with η the channel transmittance. In fact, TF-QKD is a kind of MDI-QKD but based on single-photon detection. In this paper, we propose a different PM-QKD based on single-photon entanglement, referred to as single-photon entanglement-based phase-matching (SEPM)-QKD, which can be viewed as a time-reversed version of the TF-QKD. Detection loopholes of the standard Bell test, which often occur in DI-QKD over long transmission distances, are not present in this protocol because the measurement settings and key information are the same quantity which is encoded in the local weak coherent state. We give a security proof of SEPM-QKD and demonstrate in theory that it is secure against all collective attacks and beam-splitting attacks. The simulation results show that the key rate enjoys a bound of O(sqrt{{boldsymbol{eta }}}) with respect to the transmittance. SEPM-QKD not only helps us understand TF-QKD more deeply, but also hints at a feasible approach to eliminate detection loopholes in DI-QKD for long-distance communications.
Highlights
Quantum key distribution (QKD), a secure communication method to enabling a secret random number string to be shared by two well-separated parties, says Alice and Bob, has been proven to be robust against channel attacks and against the power of quantum computation[1,2]
This single-photon entanglement-based phase-matching (SEPM)-quantum key distribution (QKD) is a time-reversed version of twin field (TF)-QKD, in which the secret key is encoded in wave space characterized by the phase value
Measurement settings in SEPM-QKD, like quantum keys, are encoded in the phase of the locally coherent state, so the detection loophole is closed
Summary
Quantum key distribution (QKD), a secure communication method to enabling a secret random number string to be shared by two well-separated parties, says Alice and Bob, has been proven to be robust against channel attacks and against the power of quantum computation[1,2]. The measurement-device-independent (MDI)-QKD proposed latter is based on the correlation measurement of a two-photon state and closed all detection loopholes[25,30]. Single-photon-entanglement-based DI-QKD was proposed in which the key is extracted according to whether Alice or Bob has detected that photon[46]. We propose single-photon entanglement-based phase-matching (SEPM)-QKD, which is a TF-QKD with quantum entanglement. In this protocol, single-photon entanglement provides the quantum link in the communications between Alice and Bob, who choose the two groups of phases to encode the key. We compare the key rate of SEPM-QKD with the wave-state-based QKD, as for TF(PM)-QKD and single-photon-based QKD, like the BB84- and MDI-QKD protocols
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