通用0级MEMS封装的热机械设计，采用芯片封盖和Through Silicon Via

2010 11th International Thermal, Mechanical & Multi-Physics Simulation, and Experiments in Microelectronics and Microsystems (EuroSimE) Pub Date : 2010-04-26 DOI:10.1109/ESIME.2010.5464539

B. Vandevelde, R. Jansen, S. Bouwstra, N. Pham, B. Majeed, P. Limaye, E. Beyne, H. Tilmans

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引用次数: 4

摘要

本文介绍了一种用于MEMS芯片封装的先进零级封盖技术的热机械设计。封装方法使用金属间化合物(IMC)键合用盖密封MEMS芯片，并使用Through Silicon Via (TSV)提供从MEMS芯片到第二级基板(LTCC或PCB)的电气连接。采用先进的基于有限元法的热-力学模拟来估计加工和温度循环对结构中引起的机械应力和变形的影响。特别关注刚性CuSn IMC键，使用聚合物电介质的铜TSV以及在1 bar(内部真空)和90 bar(模拟复模)压力下的帽挠度。最后，研究了在LTCC基板和FR4印刷电路板上分别用CuSn焊点连接组装MEMS封装对封装可靠性、帽挠度以及MEMS位置的应变和锚点旋转的影响。

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Thermo-mechanical design of a generic 0-level MEMS package using chip capping and Through Silicon Via's

This paper describes the thermo-mechanical design of an advanced zero-level capping technology used for packaging of a MEMS die. The package approach uses Intermetallic Compound (IMC) bonding to seal the MEMS die with a cap, and uses Through Silicon Via's (TSV) to provide the electrical connections from the MEMS die to the second level substrate (LTCC or PCB). Advanced FEM based thermo-mechanical simulations are performed to estimate the impact of processing and temperature cycling on the mechanical stresses and deformations induced in the structure. Special focus goes to the rigid CuSn IMC bond, the copper TSV using a polymer dielectric and the cap deflection under a pressure of 1 bar (vacuum inside) and 90 bar (simulating overmoulding). Finally, the impact of assembling the MEMS package on an LTCC substrate and an FR4 printed circuit board with CuSn, respectively solder connections is investigated with respect to the package reliability, the cap deflection and the strain and anchor rotation at location of the MEMS.

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2010 11th International Thermal, Mechanical & Multi-Physics Simulation, and Experiments in Microelectronics and Microsystems (EuroSimE)

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