Encoding Multifunctional Nanostructured Metasurfaces

TL;DR

This paper demonstrates how nanostructured metasurfaces can be engineered to encode optical information for applications like chemical detection, biomolecular sensing, colorful imaging, and holography, leveraging their plasmonic resonances.

Contribution

It introduces a method to encode multifunctional optical responses into metallic nanostructured metasurfaces for diverse sensing and imaging applications.

Findings

Encoded metasurfaces detect chemical and biomolecular interactions.

They display colorful graphic images.

They create multichannel holograms.

Abstract

Metasurfaces offer unconventional control of light to shape optical wavefronts within two-dimensional nanoscale structures. A nanostructured metallic thin film can establish an exclusive relationship between its surface structure and optical spectrum. The unique structural features, continuous metal coverage and smooth surface profile, can help obtain highly coherent plasmonic resonances that strongly depend on the structural parameters of nanostructured surfaces. It allows us to encode optical responses and information into a structural format on a variety of materials. We show experimentally that the nanostructured metasurfaces can be encoded to detect and display chemical and biomolecular interactions, show colorful graphic images, and create multichannel holograms.