OPC Methodology To Overcome Mask Error Effect On Below 0.25 um Lithography Generation

Digest of Papers. Microprocesses and Nanotechnology'98. 198 International Microprocesses and Nanotechnology Conference (Cat. No.98EX135) Pub Date : 1998-07-13 DOI:10.1109/IMNC.1998.729965

Keeho Kim, S. Madhavan, J. Lilygren

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Abstract

1. Motivation Lithography for below 0.25 um generation strongly demands OPC(Optica1 Proximity Correction) technics to achieve the better pattem fidelity that normally improves overlay margin, CD tolerance, Device characteristics such as leakage current margin and etc. The first step to design mask layout having OPC should be simulation. Normally, the main tasks of this simulation step are of making decision the best type and dimension of OPC. However, sometimes real pattern results on wafer level exposed by the mask that is designed with based on simulation, are different from designer’s expectation. This phenomenon is explicitly getting worse and worse due to the increasing of mask error when going to 4 x reticle and aggressive OPC patterns for below 0.25 um generation device. In this paper, we try to build up new simulation methodology to obtain the better matching results between simulation and real experimental results.

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在0.25微米以下光刻中克服掩模误差影响的OPC方法

1. 0.25 um以下一代的激励光刻强烈要求OPC(光学邻近校正)技术，以实现更好的模式保真度，通常可以改善覆盖裕度，CD公差，漏电流裕度等器件特性。设计具有OPC的掩模布局的第一步应该是仿真。通常，该仿真步骤的主要任务是确定OPC的最佳类型和尺寸。然而，基于仿真设计的掩模所暴露的晶圆级上的真实图案结果有时与设计者的期望不同。对于低于0.25 um的生成设备，当达到4倍网线和侵略性OPC模式时，由于掩模误差的增加，这种现象显然变得越来越糟。本文试图建立一种新的仿真方法，使仿真结果与实际实验结果更好地匹配。

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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Digest of Papers. Microprocesses and Nanotechnology'98. 198 International Microprocesses and Nanotechnology Conference (Cat. No.98EX135)

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