Quantum Interference of Cavity Light Induced by a Single Atom in Double Well

Interference in photons emitted from multiple atoms has been studied extensively. We show that a single atom can induce interference in its emitted light when tunnelling in a double-well potential coupled to an optical cavity. The phase in the cavity field interference can be modulated by the double-well spacing. By controlling the coherent tunnelling, blockade of single-photon excitations is found in the destructive interference regime, where super-Poissonian bunched light is generated. Furthermore, we show that the atomic flux of the coherent tunnelling motion generates chiral cavity fields. The direction of the chirality oscillates for many cycles before the decoherence of the atomic motion and the decay of the cavity photons. Our work opens new ways for manipulating photons with controllable quantum states of atoms for quantum information applications.