Quantum key distribution (QKD) provides ultimate cryptographic security based on the laws of quantum mechanics. For point-to-point QKD protocols, the security of the generated key is compromised by detector side channel attacks. This problem can be solved with measurement device independent QKD (mdi-QKD). However, mdi-QKD has shown limited performances in terms of the secret key generation rate, due to post-selection in the Bell measurements. We show that high dimensional (Hi-D) encoding (qudits) improves the performance of current mdi-QKD implementations. The scheme is proven to be unconditionally secure even for weak coherent pulses with decoy states, while the secret key rate is derived in the single photon case. Our analysis includes phase errors, imperfect sources and dark counts to mimic real systems. Compared to the standard bidimensional case, we show an improvement in the key generation rate. * luca.delantonio@nbi.ku.dk † dabac@fotonik.dtu.dk to increase the dimension of the Hilbert space [19-23] for standard QKD. We propose a protocol, where Alice and Bob generate qudits (quantum states in N -dimensions) encoded in different paths or time slots of the photons. These photons then interfere at Charlie's Beam Splitters (BS), as shown in Fig. 1. As discussed below, the measurement projects the qubits into a two dimensional subspace, which can be used for QKD. In the following, we analyse this high dimensional mdi-QKD protocol, considering the main sources of errors, such as, imperfect photon generation, dark counts and (unknown) phase shifts. We prove that high dimensional mdi-QKD is unconditionally secure for coherent states with the decoy state technique [15,24], and analyse the key generation rate for single photon sources. In analogy to a similar result for standard QKD [23], we find that our Hi-D mdi-QKD protocol is advantageous, particularly in the detector saturation regime, where the time between photon clicks at Charlie's detectors is comparable to the detectors' dead time τ d . We study the protocol both for time and space encoding, and analyse the practical constraints that make one encoding better than the other. A different Hi-D mdi-QKD scheme was proposed in Ref. [18], but remains experimentally unfeasible, since discriminating Bell states in high dimensions is impossible by simple means [25,26]. In comparison, our protocol can be implemented without significant increase in the complexity of existing setups. In particular, for weak coherent states and time encoding, no change in the hardware is required.
Protocol definitionMost QKD protocols are based on mutually unbiased bases (MUBs). Usually, the computational Z basis ({|0 , |1 } for qubits) is less susceptible to errors than arXiv:1809.04405v1 [quant-ph]
