A practical bilayer bottom antireflective coating (BARC) process, consisting of an upper conventional organic film and a lower amorphous-Si blackout film, is introduced to realize highly antireflective performance and efficient pattern-transfer performance simultaneously. The application of a thin-resist process for KrF imaging to 130 nm device fabrication is also investigated including a practical pattern-transfer process, especially in the gate layer and the metal-wiring layer. It is demonstrated that no standing-wave effects in the resist are observed due to the effective bilayer BARC structure; furthermore, the resist patterns, which are 215 nm thick, are successfully transferred to the substrates in the gate layer and the metal-wiring layer. Finally, experimental and simulation results suggest that the thin-resist process, in combination with the practical bilayer BARC process using KrF imaging featuring a numerical aperture of 0.68 and a partial coherency of 0.75 with a 2/3 annular aperture, could g...
[1]
Timothy A. Brunner,et al.
Approximate models for resist processing effects
,
1996,
Advanced Lithography.
[2]
Effect of thin film interference on process latitude in deep ultraviolet lithography
,
1995
.
[3]
Mark L. Schattenburg,et al.
Optically matched trilevel resist process for nanostructure fabrication
,
1995
.
[4]
Daisuke Kawamura,et al.
Resist design for resolution limit of KrF imaging towards 130 nm lithography
,
1998
.
[5]
Alois Gutmann,et al.
Impact of reduced resist thickness on deep ultraviolet lithography
,
1996
.
[6]
Shoji Mimotogi,et al.
Viability of conventional KrF imaging for 150 nm lithography
,
1997
.
[7]
Edward K. Pavelchek,et al.
Tunable AR for DUV lithography
,
1997,
Advanced Lithography.