平版印刷术
临界尺寸
电子束光刻
材料科学
过程(计算)
抵抗
光学
X射线光刻
噪音(视频)
建模与仿真
纳米光刻
维数(图论)
阴极射线
三维建模
计算机科学
光电子学
电子
纳米技术
人工智能
模拟
物理
图像(数学)
数学
操作系统
图层(电子)
量子力学
纯数学
替代医学
病理
制作
医学
作者
Dehua Li,Soo-Young Lee,Jin Choi,Seom-Beom Kim,Chan-Uk Jeon
摘要
Computational lithography is typically based on a model representing the lithographic process where a typical model consists of three components, i.e., line spread function, conversion formula (exposure-to-developing rate conversion), and noise process (exposure fluctuation). In our previous study, a practical approach to modeling the e-beam lithographic process by deriving the three components directly from SEM images was proposed. However, a 2D model of a substrate system was employed; i.e., the exposure variation along the resist-depth dimension was not considered. In this study, the possibility of improving the accuracy of modeling using a 3D model is investigated. The 3D model is iteratively determined by modeling the critical dimension estimated based on the model to those measured in SEM images. This paper describes the 3D modeling approach and new optimization procedures and discusses in detail the results from an extensive simulation for an accuracy analysis of the 3D modeling approach.
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