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Infrared beam-shaping on demand via tailored geometric phase metasurfaces employing the plasmonic phase-change material In3SbTe2

Lukas Conrads, Florian Bontke, Andreas Ulm, Paul Buske, Matthias Wuttig, Robert Schmitt, Carlo Holly, Thomas Taubner

2025Nature Communications25 citationsDOIOpen Access PDF

Abstract

Abstract Conventional optical elements are bulky and limited to specific functionalities, contradicting the increasing demand of miniaturization and multi-functionalities. Optical metasurfaces enable tailoring light-matter interaction at will, especially important for the infrared spectral range which lacks commercially available beam-shaping elements. While the fabrication of those metasurfaces usually requires cumbersome techniques, direct laser writing promises a simple and convenient alternative. Here, we exploit the non-volatile laser-induced insulator-to-metal transition of the plasmonic phase-change material In 3 SbTe 2 (IST) for optical programming of large-area metasurfaces for infrared beam-shaping. We tailor the geometric phase of metasurfaces with rotated crystalline IST rod antennas to achieve beam steering, lensing, and beams carrying orbital angular momenta. Finally, we investigate multi-functional and cascaded metasurfaces exploiting enlarged holography, and design a single metasurface creating two different holograms along the optical axis. Our approach facilitates fabrication of large-area metasurfaces within hours, enabling rapid-prototyping of customized infrared meta-optics for sensing, imaging and quantum information.

Topics & Concepts

HolographyPlasmonFabricationMiniaturizationOpticsMaterials scienceOptoelectronicsPhotonicsLaserBeam steeringInfraredPhase (matter)Beam (structure)NanotechnologyPhysicsAlternative medicineMedicinePathologyQuantum mechanicsMetamaterials and Metasurfaces ApplicationsOrbital Angular Momentum in OpticsPlasmonic and Surface Plasmon Research
Infrared beam-shaping on demand via tailored geometric phase metasurfaces employing the plasmonic phase-change material In3SbTe2 | Litcius