Single-Shot Multispectral Encoding: Advancing Optical Lithography for Encryption and Spectroscopy.

Hyewon Shim, Geonwoong Park, Hyunsuk Yun,Sunmin Ryu,Yong-Young Noh,Cheol-Joo Kim

NANO LETTERS（2024）

Inst Basic Sci IBS | Pohang Univ Sci & Technol POSTECH | POSTECH

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Abstract

Most modern optical display and sensing devices utilize a limited number of spectral units within the visible range, based on human color perception. In contrast, the rapid advancement of machine-based pattern recognition and spectral analysis could facilitate the use of multispectral functional units, yet the challenge of creating complex, high-definition, and reproducible patterns with an increasing number of spectral units limits their widespread application. Here, we report a technique for optical lithography that employs a single-shot exposure to reproduce perovskite films with spatially controlled optical band gaps through light-induced compositional modulations. Luminescent patterns are designed to program correlations between spatial and spectral information, covering the entire visible spectral range. Using this platform, we demonstrate multispectral encoding patterns for encryption and multivariate optical converters for dispersive optics-free spectroscopy with high spectral resolution. The fabrication process is conducted at room temperature and can be extended to other material and device platforms.

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Key words

multispectral optical element,optical lithography,luminescent pattern,compressive spectroscopy,optical encryption,semiconductor alloy pattern

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