Asymmetric nanocavity: from color-selective reflector to broadband near-infrared absorber

RSC Applied Interfaces Pub Date : 2025-05-16 DOI:10.1039/D4LF00421C

Kirtan P. Dixit and Don A. Gregory

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Abstract

Advances in photonics and energy systems increasingly rely on engineering material interfaces to achieve multifunctional performance. In this study, we present a scalable, lithography-free design for asymmetric Fabry–Perot nanocavities (AFPNs) that function as both narrowband visible reflectors and broadband near-infrared absorbers. By utilizing a dielectric–semiconductor–dielectric spacer with silicon as a critical material, we demonstrate tunable color reflection with just a 5 nm thickness variation and over 80% broadband absorption across the 0.8–1.3 μm range. Adding an anti-reflection coating further extends absorption efficiency to near unity while preserving color fidelity. This planar architecture reduces angular sensitivity and eliminates the need for complex nanopatterning, addressing key challenges in scalability and optical efficiency. These findings highlight a versatile platform for optical coatings in display technologies, photovoltaics, and thermal emitters, advancing the design of multifunctional nanophotonic devices.

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不对称纳米腔：从选色反射器到宽带近红外吸收器

光子学和能源系统的进步越来越依赖于工程材料接口来实现多功能性能。在这项研究中，我们提出了一种可扩展的、无光刻的非对称Fabry-Perot纳米腔（afpn）设计，它既可以作为窄带可见反射器，也可以作为宽带近红外吸收器。通过使用以硅为关键材料的介电-半导体-介电间隔材料，我们展示了可调谐的颜色反射，厚度变化仅为5 nm，在0.8-1.3 μm范围内的宽带吸收超过80%。添加抗反射涂层进一步将吸收效率扩展到接近统一，同时保持色彩保真度。这种平面结构降低了角度灵敏度，消除了对复杂纳米图形的需求，解决了可扩展性和光学效率方面的关键挑战。这些发现突出了显示技术、光伏和热辐射器件中光学涂层的通用平台，推进了多功能纳米光子器件的设计。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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RSC Applied Interfaces

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