Multimode Entangled Squeezed Light Generation and Propagation in a Coupled-Cavity Photonic Crystal

Abstract: We present an efficient and accurate method for modeling the generation and propagation of quantum states of light in lossy coupled-cavity systems. We apply our approach to the design and modeling of a multimode photonic crystal coupled-cavity system for the generation of entangled squeezed states of light on-chip. The system consists of a three-mode, three-defect resonant structure coupled to three coupled-resonator optical waveguides (CROWs) in a square lattice silicon photonic crystal slab. We model the system using a basis of 184 non-orthogonal lossy quasi-modes. A two-mode squeezed thermal state of light is generated via degenerate spontaneous four-wave mixing in the resonant structure, which is pumped with a Gaussian pulse via a pump-CROW. The generated entangled signal and idler pulses of light are coupled out of the resonant structure into the two output-CROWs. Due to careful design of the resonant structure and the CROWs, the signal and idler light in the two output CROWs remains entangled even after propagating tens of cavities down the CROWs. Our approach is general and computationally efficient and thus can be applied to modeling the generation and propagation of quantum states of light in a wide variety of coupled-cavity photonic structures.