Optical properties of nitride-rich SiNx and its use in CMOS-compatible near-UV Bragg filter fabrication

Q2 Engineering Optical Materials: X Pub Date : 2024-08-24 DOI:10.1016/j.omx.2024.100348

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Abstract

Nitride-rich silicon-nitride (SiN $_{x}$ ) is being explored for its potential as a suitable optical material for use in microsystems operating in the near-UV spectral range. Although silicon-rich SiN $_{x}$ is widely accepted as a CMOS-compatible dielectric and micromechanical material, its optical absorption limits application to the visible to near-IR spectral range. However, this work shows that a balance can be achieved between a sufficiently high index of refraction ( $n >$ 2) and an acceptable optical loss ( $k < 1 0^{- 3}$ ) in nitride-rich SiN $_{x}$ of appropriate composition ( $x \sim 1.45$ ). Bragg reflectors with a design wavelength at $λ_{o}$ = 330 nm are used for validation. PECVD is used for sample preparation and experiments confirm that the spectral range available for use of SiN $_{x}$ -based optical microsystems extends to wavelengths as low as 300 nm.

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富氮化物氮化硅的光学特性及其在 CMOS 兼容型近紫外布拉格滤波器制造中的应用

富氮化物氮化硅（SiNx）作为一种适用于在近紫外光谱范围内工作的微系统的光学材料，其潜力正在被挖掘。尽管富含氮化硅的 SiNx 被广泛认为是一种与 CMOS 兼容的电介质和微机械材料，但它的光吸收限制了其在可见光到近红外光谱范围内的应用。然而，这项工作表明，在适当成分（x∼1.45）的富氮化硅 SiNx 中，可以在足够高的折射率（n> 2）和可接受的光学损耗（k<10-3）之间实现平衡。设计波长为 λo= 330 nm 的布拉格反射器用于验证。样品制备采用 PECVD 技术，实验证实，基于 SiNx 的光学微系统的光谱范围可延伸至低至 300 纳米的波长。

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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