基于机器学习方法的工艺偏差检测光谱椭偏成像

T. Alcaire, D. B. Cunff, V. Gredy, J. Tortai
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引用次数: 3

摘要

光谱椭偏仪是一种灵敏的测量技术,可以精确测量特定专用测量目标上不同层的厚度和折射率。与此同时,光学缺陷技术被广泛应用于生产线上,用于检查大量的模具,并在工艺流程中捕捉物理和图案缺陷。因此,在全晶圆尺度上利用测量工具的灵敏度,探索一种重叠测量和缺陷的新方法成为人们感兴趣的问题。在我们的案例中,光谱椭偏仪的光学响应是直接在模具上收集的,以捕获特定的偏差,如薄膜性能和厚度变化。这是一种创新的策略,需要一种无模型的方法,结合自动椭偏映射生成和通过机器学习算法进行智能分类。在本文中,我们将在两个工业用例中介绍这种方法,并解释如何实现图像分类算法来自动检测后者的过程漂移。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Spectroscopic Ellipsometry Imaging for Process Deviation Detection via Machine Learning Approach
Spectroscopic ellipsometry is a very sensitive metrology technique to accurately measure the thickness and the refractive index of the different layers present on specific dedicated metrology targets. In parallel, optical defectivity techniques are widely implemented in production lines to inspect a large number of dies and catch physical and patterning defects during the process flow. It becomes then of interest to explore a new approach overlapping metrology and defectivity by using the sensitivity of metrology tools on a full wafer scale. In our case, spectroscopic ellipsometry’s optical response was collected directly on the dies to capture specific deviations such as film properties and thickness variation. This is an innovative strategy that requires a model-less approach, combining an automatic ellipsometry mapping generation and a smart classification via a machine learning algorithm. In this paper, we will present such approach on two industrial use cases and explain how an image classification algorithm can be implemented to automatically detect the process drift on the latter.
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