高度可控、可靠的超薄聚苯乙烯沉积

IF 4.7 Q2 NANOSCIENCE & NANOTECHNOLOGY
Yaoping Liu, Dongyang Kang, Wangzhi Dai, Haida Li, Wei Wang, Yu-Chong Tai
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引用次数: 4

摘要

由于其优异的阻隔性和易于制造的特性,聚对二甲苯在微机电系统中得到了广泛的应用。一种厚度小于100?通常需要Nm来精确调整基板的表面特性或保护功能单元。市售的常规聚对二甲苯沉积是一种由二聚体质量决定的化学气相沉积工艺,具有高输出(即厚度控制方面的低沉积精度),约为1.6?μm/g(薄膜厚度与负载二聚体质量之比)。因此,很难控制和可靠地制备厚度小于100?Nm,要求二聚体质量小于62.5 mg。本文报道了一种制备超薄聚对二甲苯薄膜的方法,其标称厚度可达1nm。在内部放置一个自制的沉积室,并通过一个特征尺寸小于1?mm的微孔与常规机器室连接。根据自由分子流理论,沉积室内压力可预测可控地降低,从而实现超低的聚对二甲苯沉积产量,低至0.08?成功地得到了Nm /g。与直接沉积法相比,沉积精度提高了4个数量级。这种高度可控和可靠的超薄聚对二甲苯沉积技术将在柔性电子和生物医学微器件中找到有前途的应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Highly controllable and reliable ultra-thin Parylene deposition

Highly controllable and reliable ultra-thin Parylene deposition

Thanks to the excellent barrier property and fabrication accessibility, Parylene has been actively used in the microelectromechanical system. An ultra-thin Parylene film with thickness smaller than 100?nm is usually required to precisely tune the surface property of substrate or protect the functional unit. The commercially available regular Parylene deposition is a dimer mass determined chemical vapor deposition process with a high output (i.e. a low deposition precision in term of thickness control), around 1.6?μm/g (the ratio of film thickness to the loaded dimer mass) for the machine in the author’s lab. Therefore, it is hard to controllably and reliably prepare a Parylene film with thickness smaller than 100?nm, which requires a dimer mass less than 62.5?mg. This paper reported a method to prepare ultra-thin Parylene films with the nominal thickness down to 1?nm. A home-made deposition chamber was put inside and connected with the regular machine chamber through a microfabricated orifice with feature size smaller than 1?mm. According to the free molecular flow theory, the pressure inside the deposition chamber can be predictably and controllably reduced, thereby an ultra-low output of Parylene deposition, as low as 0.08?nm/g, was successfully obtained. The deposition precision was increased by 4 orders of magnitude compared to that of a direct Parylene deposition. This highly controllable and reliable ultra-thin Parylene deposition technique will find promising applications in flexible electronics and biomedical microdevices.

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来源期刊
Micro and Nano Systems Letters
Micro and Nano Systems Letters Engineering-Biomedical Engineering
CiteScore
10.60
自引率
5.60%
发文量
16
审稿时长
13 weeks
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