MEMS post-processing of MPW dies using BSOI carrier wafers

SPIE MOEMS-MEMS Pub Date : 2008-02-07 DOI:10.1117/12.763217

A. Mukherjee, M. Kiziroglou, A. Holmes, E. Yeatman

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引用次数: 7

Abstract

Multi-project-wafer (MPW) services provide an economical route for prototyping of new electronic circuit designs. However, addition of MEMS functionality to MPW circuits by post-processing (also known as MEMS-last processing) is difficult and inefficient because MPW typically yields individual dies. One solution to this problem is to embed the MPW dies in a carrier wafer prior to MEMS processing. We have developed a process which allows 300 μm-thick CMOS dies to be embedded in a BSOI (bonded silicon-on-insulator) carrier prior to low-temperature processing for integration of metal MEMS. Deep reactive ion etching (DRIE) with an STS Multiplex ICP etcher is used to form cavities in the device layer of a BSOI wafer. By adjusting the passivation and etching cycles, the DRIE process has been optimized to produce near-vertical sidewalls when stopping on the buried oxide layer. The cavity sizes are closely matched to the die dimensions to ensure placement of the dies to within ±15 μm. Dies are placed in all the cavities, and then a photoresist layer is deposited by spin-coating and patterned to provide access to the required IC contact pads. The photoresist has the dual role of securing the dies and also planarizing the top surface of the carrier. After an appropriate baking cycle this layer provides a suitable base for multi-level electroplating or other low-temperature MEMS processing.

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基于BSOI载流子晶圆的MPW模的MEMS后处理

多项目晶圆(MPW)服务为新电子电路设计的原型设计提供了一条经济的途径。然而，通过后处理(也称为MEMS最后处理)将MEMS功能添加到MPW电路中是困难和低效的，因为MPW通常会产生单个芯片。解决这个问题的一种方法是在MEMS处理之前将MPW芯片嵌入载流子晶圆中。我们已经开发出一种工艺，可以在低温加工之前将300 μm厚的CMOS芯片嵌入BSOI(键合绝缘体上硅)载流子中，以集成金属MEMS。采用STS多路ICP刻蚀器进行深度反应离子刻蚀(DRIE)，在BSOI晶圆的器件层中形成空腔。通过调整钝化和蚀刻周期，DRIE工艺得到了优化，当停在埋藏的氧化层上时，可以产生接近垂直的侧壁。型腔尺寸与模具尺寸紧密匹配，确保模具放置精度在±15 μm以内。在所有腔内放置模具，然后通过旋转镀膜沉积光刻胶层并进行图片化，以提供所需IC触点垫的访问。光刻胶具有固定模具和使载体顶面平面化的双重作用。经过适当的烘烤循环后，该层为多层电镀或其他低温MEMS加工提供了合适的基础。

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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SPIE MOEMS-MEMS

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