DocumentCode
1131357
Title
Enhanced resolution for future fabrication
Author
Fritze, Michael ; Chen, Chenson K. ; Astolfi, David K. ; Yost, Donna Ruth ; Burns, James A. ; Chang-Lee Chen ; Gouker, Pascale M. ; Suntharalingam, Vyshnavi ; Wyatt, Peter W. ; Keast, Craig L.
Author_Institution
Lincoln Lab., MIT, Lexington, MA, USA
Volume
19
Issue
1
fYear
2003
fDate
1/1/2003 12:00:00 AM
Firstpage
43
Lastpage
47
Abstract
We have developed resolution-enhanced optical lithography processes that have enabled us to fabricate devices with deep sub-100 nm feature sizes. Isolated gate features were resolved down to 40 nm in resist using optimized phase-shift lithography processes. The addition of a small reactive ion etch (RIE) etch bias allowed us to fabricate transistors with gate lengths in the range 9-25 nm. This was achieved using standard 248 nm optical stepper, photoresist, and RIE technology. The capability is valuable for providing robust fabrication processes for advanced device technology studies. Double-exposure phase-shift imaging is also achieving growing industry acceptance with promising new results recently reported by UMC and Intel. These results show that optical lithography with aggressive resolution enhancements will likely be able to meet the needs of the semiconductor industry for the rest of this decade, pushing out the anticipated introduction of next-generation lithography (NGL) technologies further into the future.
Keywords
photolithography; photoresists; sputter etching; 248 nm; 40 to 100 nm; 9 to 25 nm; double-exposure phase-shift imaging; optical lithography; optical stepper; phase-shift lithography; photoresist; reactive ion etching; resolution enhancement technique; semiconductor manufacturing; transistor fabrication; Electronics industry; Etching; Lithography; Optical device fabrication; Optical devices; Optical imaging; Particle beam optics; Resists; Robustness; Transistors;
fLanguage
English
Journal_Title
Circuits and Devices Magazine, IEEE
Publisher
ieee
ISSN
8755-3996
Type
jour
DOI
10.1109/MCD.2003.1175107
Filename
1175107
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