Litcius/Paper detail

Super-resolution imaging based on radially polarized beam induced superoscillation using an all-dielectric metasurface

Kaixiang Cheng, ZhenXing Li, Jingjing Wu, Zheng-Da Hu, Jicheng Wang

2022Optics Express34 citationsDOIOpen Access PDF

Abstract

Superoscillation is a kind of phenomenon which can generate oscillation faster than the fastest component of a band-limited function. For optics, superoscillation is generated by coherence of low spatial frequency waves. It can bring a localized region named "hot spot", which has a smaller size than the diffraction-limit, and this character has potential applicaions in super-resolution imaging. Using a high-order radially polarized Laguerre-Gaussian beam tightly focused by high-NA objective lens, we can easily obtain and control the superoscillation hot spot. Using a metasurface, which has compact volume and sub-wavelength pixel size, we can generate the high-order radially polarized Laguerre-Gaussian beam more simply than conventional methods like using a liquid crystal mode converter. We first analyze the properties of unit cells of the metasurface and simulate the performance of the metasurface. Then we analyze the property of the tightly focused high-order radially polarized Laguerre-Gaussian beam and design a super-resolution imaging system using our designed metasurface. Therefore, the 2-fold lateral resolution enhancement is realized in our approach. This method can be used to improve lateral resolution in conventional confocal imaging systems.

Topics & Concepts

OpticsBeam (structure)Coherence (philosophical gambling strategy)PhysicsImage resolutionPolarization (electrochemistry)Liquid crystalMaterials sciencePixelGhost imagingOptical coherence tomographyConfocalOscillation (cell signaling)Spatial frequencyResolution (logic)Light beamLaser beamsSpatial coherenceImage qualityHolographyImage processingTemporal resolutionPolarimetryLiquid-crystal displayMetamaterials and Metasurfaces ApplicationsOrbital Angular Momentum in OpticsPlasmonic and Surface Plasmon Research