Advances in Stress Test Chips

Applications of Experimental Mechanics to Electronic Packaging Pub Date : 1997-11-16 DOI:10.1115/imece1997-1220

R. Jaeger, J. Suhling

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引用次数: 3

Abstract

Structural reliability of integrated circuit chips in electronic packages continues to be a major concern due to ever increasing die size, circuit densities, power dissipation, and operating temperatures. A powerful method for experimental evaluation of die stress distributions is the use of test chips incorporating integral piezoresistive sensors, and this paper presents a review of the state-of-the-art in silicon piezoresistive stress sensor test chips. Resistive rosettes on (100) silicon can be used to measure as many as four components of the six-component stress state whereas advanced test chips based upon (111) silicon can measure the complete stress state. However, not all of the measurements can be performed in a temperature compensated manner which is required for high accuracy results. Classic resistor rosettes suffer from reduced sensitivity due to high doping levels, and they measure values of the die surface stress averaged over a relatively large area. Advanced stress sensors based upon the piezoresistive response of field-effect transistors are expected to provide improved sensitivity and highly localized measurement of stress sensitivity. Localized high sensitivity measurement can also be provided by new van der Pauw stress sensors.

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压力测试芯片的进展

由于不断增加的芯片尺寸、电路密度、功耗和工作温度，电子封装中集成电路芯片的结构可靠性仍然是一个主要问题。使用集成压阻式传感器的测试芯片是测试模具应力分布的一种有效方法，本文综述了硅压阻式应力传感器测试芯片的最新进展。(100)硅上的电阻玫瑰花可用于测量六分量应力状态的多达四个分量，而基于(111)硅的先进测试芯片可以测量完整的应力状态。然而，并不是所有的测量都能以温度补偿的方式进行，这是高精度结果所必需的。由于高掺杂水平，传统的电阻器花环的灵敏度降低，并且它们测量的是在相对较大的面积上平均的模具表面应力值。基于场效应晶体管压阻响应的先进应力传感器有望提供更高的灵敏度和高度局部化的应力灵敏度测量。新的范德堡应力传感器也可以提供局部高灵敏度测量。

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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Applications of Experimental Mechanics to Electronic Packaging

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