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微机械加工石英晶体微结构湿法蚀刻中基于尺寸效应的尺寸补偿

Size-Effect-Based Dimension Compensations in Wet Etching for Micromachined Quartz Crystal Microstructures.

作者信息

Dong Yide, Dou Guangbin, Wei Zibiao, Ji Shanshan, Dai Huihui, Tang Kaiqin, Sun Litao

机构信息

SEU-FEI Nano-Pico Center, Key Laboratory of MEMS of Ministry of Education, Southeast University, Nanjing 210096, China.

Nanjing Jingxin Optoelectronics Research Institute, Nanjing 210096, China.

出版信息

Micromachines (Basel). 2024 Jun 14;15(6):784. doi: 10.3390/mi15060784.

DOI:10.3390/mi15060784
PMID:38930754
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11205438/
Abstract

Microfabrication technology with quartz crystals is gaining importance as the miniaturization of quartz MEMS devices is essential to ensure the development of portable and wearable electronics. However, until now, there have been no reports of dimension compensation for quartz device fabrication. Therefore, this paper studied the wet etching process of Z-cut quartz crystal substrates for making deep trench patterns using Au/Cr metal hard masks and proposed the first quartz fabrication dimension compensation strategy. The size effect of various sizes of hard mask patterns on the undercut developed in wet etching was experimentally investigated. Quartz wafers masked with initial vias ranging from 3 μm to 80 μm in width were etched in a buffered oxide etch solution (BOE, HF:NHF = 3:2) at 80 °C for prolonged etching (>95 min). It was found that a larger hard mask width resulted in a smaller undercut, and a 30 μm difference in hard mask width would result in a 17.2% increase in undercut. In particular, the undercuts were mainly formed in the first 5 min of etching with a relatively high etching rate of 0.7 μm/min (max). Then, the etching rate decreased rapidly to 27%. Furthermore, based on the etching width compensation and etching position compensation, new solutions were proposed for quartz crystal device fabrication. And these two kinds of compensation solutions were used in the fabrication of an ultra-small quartz crystal tuning fork with a resonant frequency of 32.768 kHz. With these approaches, the actual etched size of critical parts of the device only deviated from the designed size by 0.7%. And the pattern position symmetry of the secondary lithography etching process was improved by 96.3% compared to the uncompensated one. It demonstrated significant potential for improving the fabrication accuracy of quartz crystal devices.

摘要

随着石英微机电系统(MEMS)器件的小型化对于确保便携式和可穿戴电子产品的发展至关重要,基于石英晶体的微纳制造技术正变得越来越重要。然而,到目前为止,尚无关于石英器件制造尺寸补偿的报道。因此,本文研究了使用金/铬金属硬掩膜制作深沟槽图案的Z切石英晶体衬底的湿法蚀刻工艺,并提出了首个石英制造尺寸补偿策略。通过实验研究了各种尺寸的硬掩膜图案对湿法蚀刻中产生的侧向腐蚀的尺寸效应。在80℃的缓冲氧化物蚀刻溶液(BOE,HF:NHF = 3:2)中对宽度从3μm到80μm的初始通孔掩膜的石英晶片进行长时间蚀刻(>95分钟)。结果发现,较大的硬掩膜宽度会导致较小的侧向腐蚀,硬掩膜宽度相差30μm会导致侧向腐蚀增加17.2%。特别是,侧向腐蚀主要在蚀刻的前5分钟内形成,蚀刻速率相对较高,为0.7μm/分钟(最大值)。然后,蚀刻速率迅速下降至27%。此外,基于蚀刻宽度补偿和蚀刻位置补偿,提出了用于石英晶体器件制造的新解决方案。并且这两种补偿解决方案被用于制造谐振频率为32.768kHz的超小型石英晶体音叉。通过这些方法,器件关键部分的实际蚀刻尺寸仅与设计尺寸相差0.7%。与未补偿的情况相比,二次光刻蚀刻工艺的图案位置对称性提高了96.3%。这表明在提高石英晶体器件制造精度方面具有巨大潜力。

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