Characterization of Thin AlN/Ag/AlN-Reflector Stacks on Glass Substrates for MEMS Applications

Micro Pub Date : 2024-02-29 DOI:10.3390/micro4010010

Christian Behl, Regine Behlert, Jan Seiler, Christian Helke, Alexey Shaporin, Karla Hiller

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Abstract

Thin metal layers such as silver (Ag) are being utilized for various optical and plasmonic applications as well as for electrical purposes, e.g., as transparent electrodes in display devices or solar cells. This paper focuses on optical MEMS applications such as the Fabry–Pérot interferometer (FPI). Within such filters, reflector materials such as distributed Bragg reflectors (DBRs) or subwavelength gratings (SWGs) have been widely used so far, whereas metallic thin films (MTFs) were limited in application due to their comparatively higher absorption. In this paper, thin sputtered Ag layers with thicknesses of 20, 40 and 60 nm on glass substrates have been investigated, and it is shown that the absorption is very low in the visible spectral range (VIS) and increases only in near-infrared (NIR) with increasing wavelength. Thus, we consider Ag-thin layers to be an interesting reflector material at least for the VIS range, which can be easily fabricated and integrated. However, Ag is not inert and stable when exposed to the atmosphere. Hence, it needs a passivation material. For this purpose, AlN has been chosen in this contribution, which can be deposited by sputtering as well. In this contribution, we have chosen thin AlN layers for this purpose, which can also be deposited by sputtering. Thus, various AlN/Ag/AlN-reflector stacks were created and patterned by lift-off technology preferably. The fabricated reflectors were characterized with respect to adhesion, stress, cohesion, homogeneity, and most importantly, their optical properties. It was found that the thickness of the AlN can be used to adjust the reflectance–transmittance ratio in the VIS range, and influences the adsorption in the NIR range as well. Based on the measured values of the reflectors with 40 nm Ag, an exemplary transmission filter characteristics has been predicted for a wavelength range from 400 to 800 nm. Both the maximum transmittance and the full width at half maximum (FWHM) can be tuned by variation of the AlN thickness from 20 to 60 nm.

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用于微机电系统（MEMS）应用的玻璃基板上薄 AlN/Ag/AlN 反射器叠层的特性分析

银（Ag）等薄金属层正被用于各种光学和等离子应用以及电气用途，例如用作显示设备或太阳能电池的透明电极。本文重点介绍法布里-佩罗干涉仪（FPI）等光学 MEMS 应用。在此类滤波器中，分布式布拉格反射器（DBR）或亚波长光栅（SWG）等反射器材料迄今已得到广泛应用，而金属薄膜（MTF）因其相对较高的吸收率而在应用中受到限制。本文研究了玻璃基板上厚度为 20、40 和 60 nm 的溅射银薄层，结果表明其吸收率在可见光谱（VIS）范围内非常低，仅在近红外（NIR）范围内随着波长的增加而增加。因此，我们认为至少在可见光范围内，银薄层是一种有趣的反射材料，而且易于制造和集成。然而，暴露在大气中的银并不是惰性和稳定的。因此，它需要一种钝化材料。为此，本文选择了氮化铝，它也可以通过溅射沉积。为此，我们选择了氮化铝薄层，它也可以通过溅射沉积。因此，我们采用升华技术制作和图案化了各种 AlN/Ag/AlN 反射器堆栈。对制作的反射器进行了附着力、应力、内聚力、均匀性等方面的表征，最重要的是对其光学特性进行了表征。研究发现，氮化铝的厚度可用于调整可见光范围内的反射透射比，并影响近红外范围内的吸附性。根据含有 40 纳米银的反射器的测量值，我们预测了波长范围在 400 纳米到 800 纳米之间的典型透射滤波器特性。最大透射率和半最大全宽（FWHM）都可以通过 20 纳米到 60 纳米的氮化铝厚度变化来调整。

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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