论文信息 - Multi-trigger resist for electron beam lithography

Multi-trigger resist for electron beam lithography

Irresistible Materials is developing a new molecular resist system that demonstrates high-resolution capability based on the Multi-trigger concept. In a Multi-Trigger resist, multiple distinct chemical reactions in chemical amplification process must take place in close proximity simultaneously during resist exposure. Thus, at the edge of a pattern feature, where the density of photo-initiators that drive the chemical reactions is low, the amplification process ceases. This significantly reduces blurring effects and enables much improved resolution and line edge roughness while maintaining the sensitivity advantages of chemical amplification. A series of studies such as enhanced resist crosslinking, elimination of the nucleophilic quencher and the addition of high-Z additives to e-beam resist (as a means to increase sensitivity and modify secondary electron blur) were conducted in order to optimize the performance of this material. The optimized conditions allowed patterning down to 28 nm pitch lines with a dose of 248 μC/cm2 using 100kV e-beam lithography, demonstrating the potential of the concept. Furthermore, it was possible to pattern 26 nm diameter pillars on a 60 nm pitch with dose of 221μC/cm2 with a line edge roughness of 2.3 nm.

[1] A. McClelland,et al. Optimization of fullerene-based negative tone chemically amplified fullerene resist for extreme ultraviolet lithography , 2014, Advanced Lithography.

[2] Geert Vandenberghe,et al. Metal oxide EUV photoresist performance for N7 relevant patterns and processes , 2016, SPIE Advanced Lithography.

[3] Stefan Hien,et al. Collapse behavior of single layer 193- and 157-nm resists: use of surfactants in the rinse to realize the sub-130-nm nodes , 2002, SPIE Advanced Lithography.

[4] Andreas Frommhold,et al. Dynamic absorption coefficients of CAR and non-CAR resists at EUV , 2016, SPIE Advanced Lithography.

[5] William Early,et al. LER Limitations of Resist Thin Films , 2012 .

[6] Tatsuya Fujii,et al. Patterning performance of chemically amplified resist in EUV lithography , 2016, SPIE Advanced Lithography.

[7] Clifford L. Henderson,et al. Methods of controlling cross-linking in negative-tone resists , 2014, Advanced Lithography.

[8] Hideaki Tsubaki,et al. Negative-tone Imaging with EUV Exposure toward 13 nm hp , 2016 .

[9] Andreas Frommhold,et al. Towards 11nm half-pitch resolution for a negative-tone chemically amplified molecular resist platform for extreme-ultraviolet lithography , 2015, Advanced Lithography.

[10] Andreas Frommhold,et al. Optimization and sensitivity enhancement of high-resolution molecular resist for EUV lithography , 2016, SPIE Advanced Lithography.