扫描共聚焦电子显微镜:半导体器件缺陷研究的新工具

2006 13th International Symposium on the Physical and Failure Analysis of Integrated Circuits Pub Date : 2006-07-03 DOI:10.1109/IPFA.2006.250995

N. Zaluzec

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引用次数: 1

摘要

这项工作简洁地说明了SCEM为厚非光学透明半导体器件的计量研究提供有价值信息的能力。SCEM在失效分析中的应用在于它能够从极厚的试样中提供相对高分辨率的图像。通过这种方式，该仪器可以弥补光学SCOM和TEM之间的差距，前者可用于观察几微米大小的特征，而后者可以分辨原子大小的结构，但需要小于100纳米厚的样品才能达到这种分辨率。在半导体制造中，SCEM用于失效分析的主要优点是，无需显着去封装或横截面到TEM/STEM观察通常采用的厚度，即可研究缺陷或器件。这允许不受干扰地观察嵌入缺陷。SCEM的景深和焦点与SCOM一样，受到试样前后会聚角的限制。随着像差校正器的出现，这方面的SCEM将成为一个更有用的工具

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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The Scanning Confocal Electron Microscope: A New Tool for Defect Studies in Semiconductor Devices

This work illustrates succinctly the ability of the SCEM to provide valuable information for metrological studies of thick non-optically transparent semiconductor devices. The utility of SCEM to failure analysis comes from its ability to provide relatively high-resolution images from extremely thick specimens. In this way, the instrument can bridge the gap between optical SCOM useful for observing features few microns in size, to TEM which can resolve atomic sized structures but requiring specimens less than 100 nm thick to reach this resolution. The main advantage of SCEM for failure analysis in semiconductor manufacturing is to investigate defects or devices without the need to significantly de-capsulate or cross-section to thickness typically employed by TEM/STEM observations. This allows un-disturbed observation of embedded defects. Depth of field and focus of the SCEM, like the SCOM are limited by the pre and post specimen convergence angles. With the advent of aberration correctors this aspect of the SCEM will become an even more useful tool

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2006 13th International Symposium on the Physical and Failure Analysis of Integrated Circuits

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