Efficient semiquantum key distribution based on single photons in both polarization and spatial-mode degrees of freedom

In this paper, we propose an efficient semiquantum key distribution (SQKD) protocol which is based on single photons in both polarization and spatial-mode degrees of freedom. This protocol is feasible for a quantum communicant distributing a random private key to a classical communicant. This protocol need not require the classical communicant to use any quantum memory or unitary operation equipment. We validate the complete robustness of the transmissions of single photons between two communicants. It turns out that during these transmissions, if Eve wants not to be detected by two communicants, she will obtain nothing useful about the final shared key bits. Compared with Boyer et al.'s famous pioneering SQKD protocol (Phys Rev Lett 99:140501, 2007), this protocol has double quantum communication capacity, as one single photon with two degrees of freedom for generating the key bits can carry two private bits; and this protocol has higher quantum communication efficiency, as it consumes less qubits for establishing a private key of the same length. Compared with the only existing SQKD protocol with single photons in two degrees of freedom (Int J Theoret Phys 59:2807, 2020), this protocol has higher quantum communication efficiency.

Automated summary

In this paper, an efficient semiquantum key distribution (SQKD) protocol based on single photons is proposed. The protocol allows a quantum communicant to distribute a random private key to a classical communicant without the need for quantum memory or unitary operation equipment. The complete robustness of single photon transmissions between the two communicants is validated. Compared with existing protocols, this protocol has higher quantum communication efficiency and double quantum communication capacity.