用于60-80纳米ULSI制造的EB投影光刻技术

2000 Symposium on VLSI Technology. Digest of Technical Papers (Cat. No.00CH37104) Pub Date : 2000-06-13 DOI:10.1109/VLSIT.2000.852767

K. Tokunaga, F. Koba, M. Miyasaka, Y. Takaishi, K. Noda, H. Yamashita, K. Nakajima, H. Nozue

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引用次数: 2

摘要

电子束(EB)投影光刻(EPL)，如电子束步进和SCALPEL，有望成为批量生产低于0.1 /spl mu/m ulsl的下一代光刻(NGL)。采用1.0/spl倍/1.0 mm掩模图案面积(4/spl倍/)的EB散射掩模将大大提高写入吞吐量。此外，使用100 kV加速电压可以获得80 nm或更小的图案分辨率。然而，重要的是开发高灵敏度的EB电阻，以实现40片/小时或更高的写入吞吐量(8“/spl φ /)，并优化接近效应校正，以提高10 nm或更小的CD精度(3/spl σ /)。在本报告中，我们展示了使用改进的EB化学放大抗蚀剂工艺和优化的接近效应校正以及图案修饰方法制造60-80 nm ULSI的EPL。

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EB projection lithography for 60-80 nm ULSI fabrication

Electron beam (EB) projection lithography (EPL), such as the EB stepper and the SCALPEL, is expected to be next generation lithography (NGL) for mass-production of sub-0.1 /spl mu/m ULSls. Adopting an EB scattering mask with 1.0/spl times/1.0 mm mask pattern area (4/spl times/) will drastically increase the writing throughput. In addition, a pattern resolution of 80 nm or less can be obtained using a 100 kV acceleration voltage. However, it is important to develop high sensitivity EB resists for achieving the writing throughput of 40 wafers/hour or more (8"/spl phi/) and to optimize the proximity effect correction for improving the CD accuracy of 10 nm or less (3/spl sigma/). In this report, we show the EPL for 60-80 nm ULSI fabrication using improved EB chemically amplified resist process and optimized proximity effect correction accompanied with pattern modification methods.

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来源期刊

2000 Symposium on VLSI Technology. Digest of Technical Papers (Cat. No.00CH37104)

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