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Integrated non-reciprocal magneto-optics with ultra-high endurance for photonic in-memory computing

Paolo Pintus, Mario Dumont, Vivswan Shah, Toshiya Murai, Yuya Shoji, Duanni Huang, Galan Moody, John E. Bowers, Nathan Youngblood

2024Nature Photonics65 citationsDOIOpen Access PDF

Abstract

Abstract Processing information in the optical domain promises advantages in both speed and energy efficiency over existing digital hardware for a variety of emerging applications in artificial intelligence and machine learning. A typical approach to photonic processing is to multiply a rapidly changing optical input vector with a matrix of fixed optical weights. However, encoding these weights on-chip using an array of photonic memory cells is currently limited by a wide range of material- and device-level issues, such as the programming speed, extinction ratio and endurance, among others. Here we propose a new approach to encoding optical weights for in-memory photonic computing using magneto-optic memory cells comprising heterogeneously integrated cerium-substituted yttrium iron garnet (Ce:YIG) on silicon micro-ring resonators. We show that leveraging the non-reciprocal phase shift in such magneto-optic materials offers several key advantages over existing architectures, providing a fast (1 ns), efficient (143 fJ per bit) and robust (2.4 billion programming cycles) platform for on-chip optical processing.

Topics & Concepts

PhotonicsReciprocalOptical physicsPhysicsPhysical opticsBiophotonicsQuantum opticsOpticsOptoelectronicsComputer sciencePlasmaQuantum mechanicsLinguisticsPhilosophyNeural Networks and Reservoir ComputingPhotonic and Optical DevicesOptical Network Technologies
Integrated non-reciprocal magneto-optics with ultra-high endurance for photonic in-memory computing | Litcius