Deep silicon etching: current capabilities and future directions

Photonics West - Micro and Nano Fabricated Electromechanical and Optical Components Pub Date : 2014-03-07 DOI:10.1117/12.2046694

R. Westerman, L. Martinez, D. Pays-Volard, K. Mackenzie, T. Lazerand

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引用次数: 7

Abstract

Deep Reactive Ion Etching (DRIE) has revolutionized a wide variety of MEMS applications since its inception nearly two decades ago. The DRIE technology has been largely responsible for allowing lab scale technology demonstrations to become manufacturable and profitable consumer products. As applications which utilize DRIE technologies continue to expand and evolve, they continue to spawn a range of new requirements and open up exciting opportunities for advancement of DRIE. This paper will examine a number of current and emerging DRIE applications including nanotechnology, and DRIE related packaging technologies such as Through Silicon Via (TSV) and plasma dicing. The paper will discuss a number of technical challenges and solutions associated with these applications including: feature profile control at high aspect ratios, causes and elimination of feature tilt/skew, process options for fragile device structures, and problems associated with through substrate etching. The paper will close with a short discussion around the challenges of implementing DRIE in production environments as well as looking at potentially disruptive enhancements / substitutions for DRIE.

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深硅蚀刻:目前的能力和未来的方向

深度反应离子蚀刻(Deep Reactive Ion Etching, DRIE)自近20年前问世以来，已经彻底改变了各种MEMS应用。DRIE技术在很大程度上负责允许实验室规模的技术演示成为可制造和有利可图的消费产品。随着使用DRIE技术的应用程序不断扩展和发展，它们继续产生一系列新的要求，并为DRIE的发展开辟了令人兴奋的机会。本文将研究一些当前和新兴的DRIE应用，包括纳米技术，以及与DRIE相关的封装技术，如硅通孔(TSV)和等离子切割。本文将讨论与这些应用相关的一些技术挑战和解决方案，包括:高纵横比下的特征轮廓控制，特征倾斜/倾斜的原因和消除，易碎器件结构的工艺选择，以及与基板蚀刻相关的问题。本文将以简短的讨论结束，讨论在生产环境中实现DRIE所面临的挑战，以及对DRIE潜在的破坏性增强/替代。

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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Photonics West - Micro and Nano Fabricated Electromechanical and Optical Components

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