High speed silicon wet anisotropic etching for applications in bulk micromachining: a review

IF 4.7 Q2 NANOSCIENCE & NANOTECHNOLOGY
Prem Pal, Veerla Swarnalatha, Avvaru Venkata Narasimha Rao, Ashok Kumar Pandey, Hiroshi Tanaka, Kazuo Sato
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引用次数: 25

Abstract

Wet anisotropic etching is extensively employed in silicon bulk micromachining to fabricate microstructures for various applications in the field of microelectromechanical systems (MEMS). In addition, it is most widely used for surface texturing to minimize the reflectance of light to improve the efficiency of crystalline silicon solar cells. In wet bulk micromachining, the etch rate is a major factor that affects the throughput. Slower etch rate increases the fabrication time and therefore is of great concern in MEMS industry where wet anisotropic etching is employed to perform the silicon bulk micromachining, especially to fabricate deep cavities and freestanding microstructures by removal of underneath material through undercutting process. Several methods have been proposed to increase the etch rate of silicon in wet anisotropic etchants either by physical means (e.g. agitation, microwave irradiation) or chemically by incorporation of additives. The ultrasonic agitation during etching and microwave irradiation on the etchants increase the etch rate. However, ultrasonic method may rupture the fragile structures and microwave irradiation causes irradiation damage to the structures. Another method is to increase the etching temperature towards the boiling point of the etchant. The etching characteristics of pure potassium hydroxide solution (KOH) is studied near the boiling point of KOH, while surfactant added tetramethylammonium hydroxide (TMAH) is investigated at higher temperature to increase the etch rate. Both these studies have shown a potential way of increasing the etch rate by elevating the temperature of the etchants to its boiling point, which is a function of concentration of etch solution. The effect of various kinds of additives on the etch rate of silicon is investigated in TMAH and KOH. In this paper, the additives which improve the etch rate have been discussed. Recently the effect of hydroxylamine (NH2OH) on the etching characteristics of TMAH and KOH is investigated in detail. The concentration of NH2OH in TMAH/KOH is varied to optimize the etchant composition to obtain improved etching characteristics especially the etch rate and undercutting which are important parameters for increasing throughput. In this article, different methods explored to improve the etch rate of silicon have been discussed so that the researchers/scientists/engineers can get the details of these methods in a single reference.

Abstract Image

高速硅湿各向异性刻蚀在体微加工中的应用综述
湿法各向异性蚀刻技术广泛应用于硅体微加工中,用于制造微机电系统(MEMS)领域的各种微结构。此外,它最广泛地用于表面纹理,以尽量减少光的反射率,以提高晶体硅太阳能电池的效率。在湿体微加工中,蚀刻速率是影响吞吐量的主要因素。较慢的蚀刻速率增加了制造时间,因此在MEMS行业中是一个非常值得关注的问题,在MEMS行业中,湿各向异性蚀刻被用来执行硅体微加工,特别是通过下切工艺去除底部材料来制造深腔和独立的微结构。提出了几种提高硅在湿各向异性蚀刻剂中蚀刻速率的方法,有的是物理方法(如搅拌、微波辐照),有的是化学方法(加入添加剂)。在蚀刻过程中采用超声波搅拌和微波辐照可以提高蚀刻速率。然而,超声方法可能使脆弱的结构破裂,微波辐射对结构造成辐射损伤。另一种方法是将蚀刻温度提高到蚀刻剂的沸点。研究了纯氢氧化钾溶液(KOH)在沸点附近的蚀刻特性,并在较高温度下研究了表面活性剂四甲基氢氧化铵(TMAH)的加入,以提高蚀刻速率。这两项研究都表明,通过提高蚀刻剂的温度到沸点来提高蚀刻速率是一种潜在的方法,沸点是蚀刻溶液浓度的函数。研究了不同添加剂对硅在TMAH和KOH中蚀刻速率的影响。本文讨论了提高腐蚀速率的添加剂。近年来研究了羟胺(NH2OH)对TMAH和KOH刻蚀特性的影响。通过改变TMAH/KOH中NH2OH的浓度来优化蚀刻剂的组成,从而提高蚀刻性能,特别是蚀刻速率和下切量,这是提高产量的重要参数。在这篇文章中,探讨了不同的方法来提高硅的蚀刻率,以便研究人员/科学家/工程师可以在一个单一的参考文献中得到这些方法的细节。
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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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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