A physical resist shrinkage model for full-chip lithography simulations

SPIE Advanced Lithography Pub Date : 2016-03-25 DOI:10.1117/12.2239243
Peng-xin Liu, Leiwu Zheng, M. Ma, Qian Zhao, Yongfa Fan, Qiang Q. Zhang, Mu Feng, Xin Guo, Tom Wallow, K. Gronlund, R. Goossens, Gary Zhang, Yen-Wen Lu
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引用次数: 4

Abstract

Strong resist shrinkage effects have been widely observed in resist profiles after negative tone development (NTD) and therefore must be taken into account in computational lithography applications. However, existing lithography simulation tools, especially those designed for full-chip applications, lack resist shrinkage modeling capabilities because they are not needed until only recently when NTD processes begin to replace the conventional positive tone development (PTD) processes where resist shrinkage effects are negligible. In this work we describe the development of a physical resist shrinkage (PRS) model for full-chip lithography simulations and present its accuracy evaluation against experimental data.
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全片光刻模拟的物理抗蚀收缩模型
在负色调显影(NTD)后的抗蚀剂轮廓中广泛观察到强烈的抗蚀剂收缩效应,因此在计算光刻应用中必须考虑到这一点。然而,现有的光刻模拟工具,特别是那些为全芯片应用而设计的工具,缺乏抗缩建模能力,因为直到最近NTD工艺开始取代传统的正色调显影(PTD)工艺时,才需要它们,而PTD工艺的抗缩效应可以忽略不计。在这项工作中,我们描述了全芯片光刻模拟的物理抗收缩(PRS)模型的发展,并根据实验数据提出了其准确性评估。
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SPIE Advanced Lithography
SPIE Advanced Lithography
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