论文信息 - Circular apertures for contact hole patterning in 193-nm immersion lithography

Circular apertures for contact hole patterning in 193-nm immersion lithography

A novel concept of contact holes patterning for 193 nm immersion lithography is demonstrated in this study. Conventional contact holes patterning involve targeting a square printed feature on the wafer and applying optical proximity correction (OPC) such as corner serifs addition and dimensional biasing. As dimension of contact holes reduces, the resolution enhancement provided by conventional OPC methods has become limited. This is because at smaller dimension, more light is diffracted towards higher order and is not captured in the pupil plane. As a result, the corners of the printed features are rounded and features appear circular as dimension reduces. Hence, the efforts made to generate OPC assist features using a square target are inefficient. In this paper, the patterning of contact hole using circular target is demonstrated. The imaging performance of isolated and regular contact holes array is reported. Comparison with conventional approach is made. The effects of the proposed method on critical dimension (CD), depth of focus (DOF), and image contrast is investigated.

[1] George O. Reynolds. A Concept For A High Resolution Optical Lithographic System For Producing One-Half Micron Linewidths , 1986, Advanced Lithography.

[2] Kafai Lai,et al. Intensive optimization of masks and sources for 22nm lithography , 2009, Advanced Lithography.

[3] A. Vanleenhove,et al. A litho-only approach to double patterning , 2007, SPIE Advanced Lithography.

[4] J. Goodman. Introduction to Fourier optics , 1969 .

[5] Youngsuk Kang,et al. Robust double exposure flow for memory , 2006, SPIE Advanced Lithography.

[6] Yusuke Takano,et al. Below 70-nm contact hole pattern with RELACS process on ArF resist , 2003, SPIE Advanced Lithography.

[7] M. Levenson,et al. Improving resolution in photolithography with a phase-shifting mask , 1982, IEEE Transactions on Electron Devices.

[8] Will Conley,et al. Contact hole reticle optimization by using interference mapping lithography (IML) , 2004, SPIE Advanced Lithography.

[9] D. Fehrs,et al. Illuminator modification of an optical aligner , 2004 .

[10] Robert Socha,et al. Simultaneous source mask optimization (SMO) , 2005, Photomask Japan.

[11] M. Levenson,et al. The phase-shifting mask II: Imaging simulations and submicrometer resist exposures , 1984, IEEE Transactions on Electron Devices.