Unveiling True 3D Nanoscale Microstructural Evolution in Chalcogenide Nanocomposites: A Roadmap for Advanced Infrared Functionality

Oxide and non-oxide glass with tailored morphology or microstructure induced by photo-exposure and subsequent heat treatment can result in new materials with unique optical functions. Spatial control of where this local modification occurs can result in optical materials with refractive or diffractive behavior different from those found in homogeneous optical materials. We review the use of such strategies to introduce such unique optical function to commercially developed oxide and prototype chalcogenide glass ceramic media that have yielded a range of performance attributes that make them unique in applications requiring reduced size, weight, power and cost (SWAP-C). We summarize how these materials have been designed and created to yield components that combine multiple functions in a single optical element, resulting in unique performance solutions for a variety of optical systems, highlighting the future potential these materials offer.

show abstract

Unveiling True 3D Nanoscale Microstructural Evolution in Chalcogenide Nanocomposites: A Roadmap for Advanced Infrared Functionality

Cited by 5 publications

References 38 publications

Examining phase separation and crystallization in glasses with X-ray nano-computed tomography

Examining phase separation and crystallization in glasses with X-ray nano-computed tomography

Chalcogenide Glass-Ceramics for Lightweight Aberration-Minimized Infrared Gradient Refractive Index Flat Media

Engineered refractive and diffractive optical composites via photo-thermal processes

Contact Info

Product

Resources

About