Litcius/Paper detail

Broad-intensity-range optical nonreciprocity based on feedback-induced Kerr nonlinearity

Lei Tang, Jiang-Shan Tang, Haodong Wu, Jing Zhang, Min Xiao, Keyu Xia

2021Photonics Research24 citationsDOI

Abstract

Nonreciprocal light propagation plays an important role in modern optical systems, from photonic networks to integrated photonics. We propose a nonreciprocal system based on a resonance-frequency-tunable cavity and intensity-adaptive feedback control. Because the feedback-induced Kerr nonlinearity in the cavity is dependent on the incident direction of light, the system exhibits nonreciprocal transmission with a transmission contrast of 0.99 and an insertion loss of 1.5 dB. By utilizing intensity-adaptive feedback control, the operating intensity range of the nonreciprocal system is broadened to 20 dB, which relaxes the limitation of the operating intensity range for nonlinear nonreciprocal systems. Our protocol paves the way to realize high-performance nonreciprocal propagation in optical systems and can also be extended to microwave systems.

Topics & Concepts

OpticsPhotonicsIntensity (physics)Transmission (telecommunications)Kerr effectNonlinear systemLight intensityMicrowaveIntensity modulationPhysicsOptoelectronicsComputer sciencePhase modulationTelecommunicationsPhase noiseQuantum mechanicsPhotonic and Optical DevicesAdvanced Fiber Laser TechnologiesPhotorefractive and Nonlinear Optics