Litcius/Paper detail

Monolithic Chalcogenide Optical Nanocomposites Enable Infrared System Innovation: Gradient Refractive Index Optics

Myungkoo Kang, Laura Sisken, Charmayne Lonergan, Andrew Buff, Anupama Yadav, Claudia Gonçalves, Cesar Blanco, Peter Wachtel, J. David Musgraves, Alexej Pogrebnyakov, Erwan Baleine, Clara Rivero‐Baleine, Theresa S. Mayer, Carlo G. Pantano, Kathleen A. Richardson

2020Advanced Optical Materials27 citationsDOI

Abstract

Abstract The size and weight of conventional imaging systems is defined by costly non‐planar lenses and the complex lens assemblies required to minimize optical aberrations. The ability to engineer gradient refractive index (GRIN) optics has the potential to overcome constraints of traditional homogeneous lenses by reducing the number of components in optical systems. Here, an innovative strategy to realize this goal based on monolithic GRIN media created in Ge‐As‐Se‐Pb chalcogenide infrared nanocomposites is presented. A gradient heat treatment to spatially modulate the volume fraction of high refractive index Pb‐rich nanocrystals within a glass matrix is utilized, providing a GRIN profile while maintaining an optical transparency. A first‐ever correlation of material chemistry and microstructure, processing protocol, and optical property modification resulting in a prototype GRIN structure is presented. The integrated approach and mechanistic understanding illustrated by this versatile modification paradigm provides a platform for new optical functionalities in next‐generation imaging applications.

Topics & Concepts

Materials scienceChalcogenideRefractive indexLens (geology)NanocompositeChalcogenide glassOpticsPlanarOptoelectronicsInfraredGradient-index opticsHigh-refractive-index polymerNanotechnologyComputer sciencePhysicsComputer graphics (images)Phase-change materials and chalcogenidesPhotonic and Optical DevicesLiquid Crystal Research Advancements