Litcius/Paper detail

Compact Mid‐Infrared Chalcogenide Glass Photonic Devices Based on Robust‐Inverse Design

Xiaobin Lin, Maoliang Wei, Kunhao Lei, Songtao Yang, Hui Ma, Chuyu Zhong, Ye Luo, Da Li, Junying Li, Changgui Lin, Wei Zhang, Shixun Dai, Xiaoyong Hu, Lan Li, Er‐Ping Li, Hongtao Lin

2022Laser & Photonics Review16 citationsDOI

Abstract

Abstract Mid‐infrared (mid‐IR) on‐chip photonic devices have attracted increasing attention because of their potential applications in chemical and biological sensing and optical communications. In particular, chalcogenide glasses (ChGs) have long been regarded as promising materials for mid‐IR integrated photonics, owing to their broad infrared transparency, high nonlinearity, and excellent processing capabilities. Here, an inverse design approach is introduced to ChG photonic device design with a new robust inverse design method. A high‐performance mid‐IR inverse design polarization beam splitter, waveguide polarizer, mode converter, and wavelength demultiplexer are demonstrated for the first time. They all have a footprint of only several micrometers. The robust inverse design method could improve the robustness of device performance against fabrication variations and would be a general approach for designing and optimizing miniaturized chalcogenide photonic devices.

Topics & Concepts

PhotonicsChalcogenide glassChalcogenideMaterials scienceOptoelectronicsPolarizerInversePhotonic crystalRobustness (evolution)FabricationInfraredBeam splitterOpticsElectronic engineeringComputer scienceEngineeringBirefringencePhysicsLaserMathematicsBiochemistryGenePathologyGeometryChemistryAlternative medicineMedicinePhase-change materials and chalcogenidesPhotonic and Optical DevicesNonlinear Optical Materials Studies