Measurement-Induced Multimode Squeezed Light Interferometers with Scalable Architectures

Abstract: In the rapidly expanding realm of photonic quantum information processing, the role of multi-mode squeezed light interferometers is critical. These devices are pivotal in enabling a wide range of applications from quantum computing and sensing to advanced communication systems. Although linear interferometers with full programmability have been realized with up to 32 modes, scaling to hundreds of modes is hampered by exponential increases in optical losses with circuit depth. Here we present and experimentally demonstrate highly scalable, low-loss multimode squeezed light interferometer schemes, capitalizing on measurement-induced operations and a shallow circuit approach. We validate our approach through a 6-mode interferometer and subsequently demonstrate its scalability by extending the design to 400 modes. This development marks a step toward realizing large-scale Noisy Intermediate-Scale Quantum (NISQ) algorithm applications, employing shallow circuits and addressing the prevalent issue of optical losses in photonic quantum information processing.