椭圆偏振法
随机森林
决策树
谱线
支持向量机
k-最近邻算法
材料科学
人工智能
算法
计算机科学
薄膜
极化(电化学)
机器学习
分析化学(期刊)
化学
物理
纳米技术
色谱法
天文
物理化学
作者
A. Arunachalam,S. Novia Berriel,Corbin Feit,Udit Kumar,Sudipta Seal,Kanad Basu,Parag Banerjee
出处
期刊:Journal of vacuum science & technology
[American Institute of Physics]
日期:2021-12-22
卷期号:40 (1)
被引量:19
摘要
A machine learning approach is applied to estimate film thickness from in situ spectroscopic ellipsometry data. Using the atomic layer deposition of ZnO as a model process, the ellipsometry spectra obtained contains polarization data (Ψ, Δ) as a function of wavelength. Within this dataset, 95% is used for training the machine learning algorithm, and 5% is used for thickness prediction. Five algorithms—logistic regression, support vector machine, decision tree, random forest, and k-nearest neighbors—are tested. Out of these, the k-nearest neighbor performs the best with an average thickness prediction accuracy of 88.7% to within ±1.5 nm. The prediction accuracy is found to be a function of ZnO thickness and degrades as the thickness increases. The average prediction accuracy to within ±1.5 nm remains remarkably robust even after 90% of the (Ψ, Δ) are randomly eliminated. Finally, by considering (Ψ, Δ) in a limited spectral range (271–741 nm), prediction accuracies approaching that obtained from the analysis of full spectra (271–1688 nm) can be realized. These results highlight the ability of machine learning algorithms, specifically the k-nearest neighbor, to successfully train and predict thickness from spectroscopic ellipsometry data.
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