Chiral Interaction Induced Near-Perfect Photon Blockade

Based on the scattering matrix method, we theoretically demonstrate that the chiral interaction can induce the almost perfect photon blockade (PB) in the waveguide-cavity quantum electrodynamics (QED) system. The mechanism relies on the multi-photon-paths interference within the waveguide, which is clearly shown by the analytical parameter regime for g^(2)(0)≈0. When N cavities are introduced into the system, there are N optimal parameter points accordingly for the almost perfect PB, and the required chirality decreases exponentially with increasing N. Under the conditions of resonant driving and specific chirality, the output light only relies on the parity of N (N≥2), where the coherent state and single-photon state correspond to the case of system including the odd and even number of cavities, respectively. Our work offers an alternative route for achieving almost perfect PB effects by employing the chirality of system, with potential application in the on-chip single-photon source with integrability.