Scalable Optical Quantum State Synthesizer with Dual-Mode Cavity Memory

Abstract: Quantum computing with light is a promising approach to achieving large-scale quantum computation. While Gaussian operations on optical states have been successfully scaled, the generation of highly non-Gaussian states remains a critical challenge for achieving universality and fault-tolerance. However, due to the inherently weak nonlinearity in optics, creating non-Gaussian states remains challenging. A promising solution is to ``breed'' non-Gaussianity by combining multiple weakly non-Gaussian states using quantum memory systems. Here, we propose and demonstrate a scalable method for generating optical non-Gaussian states using a cavity-based quantum memory operating in continuous time. Our memory features dual-mode operation, enabling efficient switching between memory and entangling functionalities, allowing state generation and processing with minimal resources. By employing a time-domain-multiplexed breeding protocol, we successfully generated Wigner-negative states, a key requirement for quantum error correction. This work also marks the first full demonstration of continuous-time cavity-based quantum memory, encompassing the complete processes of writing, storage, and readout. These results represent a significant advancement in quantum information processing with light, providing a scalable method for generating complex non-Gaussian states essential for fault-tolerant quantum computing. Beyond advancing optical quantum computing, the techniques and insights from this work could impact a wide range of applications, from enhancing quantum communication networks to refining quantum sensing and metrology.