Litcius/Paper detail

Full-Space and Arbitrary Orbital Angular Momentum Multiplexed Beam Manipulation with a Titanium Dioxide Metadevice

Wei Zhu, Yuancheng Fan, Ruisheng Yang, Huan Zhao, Guangzhou Geng, Xuyue Guo, Peng Li, Quanhong Fu, Kangyao Sun, Changzhi Gu, Yan Zhang, Junjie Li, Fuli Zhang

2025Nano Letters7 citationsDOI

Abstract

A titanium oxide (TiO 2 ) metasurface is emerging as a promising platform for arbitrary control of visible light and has been demonstrated for metalenses, a helicity multiplexed hologram, chiral spectroscopy, and structural colors. Among these, the generated orbital angular momentum (OAM) beam endows additional freedom in complex light–matter interactions. Manipulating multiple OAM channels within a single metadevice is highly coveted, and such capability proves advantageous for the advancement of integrated photonic chips and the creation of miniaturized optical systems tailored for applications involving OAM light. Here, an all-dielectric metasurface made of spatially rotated TiO 2 nanofins is demonstrated experimentally for the generation, spatial multiplexing, and focusing of the OAM light in both angular and distance domains. In particular, our metadevice could reconstruct four different topologically charged beams into four different directions and focus in four different planes in a broadband manner. The ultracompact spatially multiplexing on-chip metadevice may inspire exterior photonic applications with versatile integrated functionalities.

Topics & Concepts

Angular momentumMultiplexingOpticsBroadbandPhysicsLight beamPhotonicsBeam (structure)Orbital angular momentum multiplexingStructured lightOptoelectronicsHelicityReflector (photography)Degrees of freedom (physics and chemistry)Focus (optics)NanophotonicsOptical communicationPhotonic crystalSpatial light modulatorOrbital angular momentum of lightEnhanced Data Rates for GSM EvolutionSpatial multiplexingAngular displacementMetamaterials and Metasurfaces ApplicationsOrbital Angular Momentum in OpticsPlasmonic and Surface Plasmon Research