论文信息 - Ultrahigh efficiency EUV contact-hole printing with chromeless phase shift mask

Ultrahigh efficiency EUV contact-hole printing with chromeless phase shift mask

Contact-hole layer patterning is expected to be one of the first applications for EUV lithography. Conventional darkfield absorber masks, however, are extremely inefficient for these layers, placing even more burden on the already challenging source power demands. To address this concern, a checkerboard phase shift mask configuration has been proposed yielding theoretical throughput gains of 5x assuming a thin-mask modeling. In this manuscript we describe the fabrication of such a mask and demonstrate its imaging performance using the SHARP EUV microscope and MET exposure tool at Lawrence Berkeley National Laboratory. For 25-nm dense features, the phase shift mask was shown to provide a throughput gain of 8x based on SHARP and 7x based on the Berkeley MET. The higher then predicted gain is expected to be due to the fact that the thin mask modeling used in the initial prediction misses shadowing effects.

[1] Dominic Ashworth,et al. The SEMATECH Berkeley MET: demonstration of 15-nm half-pitch in chemically amplified EUV resist and sensitivity of EUV resists at 6.x-nm , 2012, Advanced Lithography.

[2] Judon Stoeldraijer,et al. EUV lithography performance for manufacturing: status and outlook , 2016, SPIE Advanced Lithography.

[3] Hans Meiling,et al. Performance optimization of MOPA pre-pulse LPP light source , 2015, Advanced Lithography.

[4] Farhad Salmassi,et al. The SEMATECH high-NA actinic reticle review project (SHARP) EUV mask-imaging microscope , 2013, Photomask Technology.

[5] Scott Daniel Hector,et al. Design and method of fabricating phase-shift masks for extreme-ultraviolet lithography by partial etching into the EUV multilayer mirror , 2003, SPIE Advanced Lithography.

[6] Ted Liang,et al. EUV progress toward HVM readiness , 2016, SPIE Advanced Lithography.

[7] Kenneth A. Goldberg,et al. Status of EUV micro-exposure capabilities at the ALS using the 0.3-NA MET optic , 2004, SPIE Advanced Lithography.