Title :
A scaled 0.25- mu m bipolar technology using full e-beam lithography
Author :
Cressler, John D. ; Warnock, James ; Coane, Philip J. ; Chiong, Kaolin N. ; Rothwell, Mary E. ; Jenkins, Keith A. ; Burghartz, Joachim N. ; Petrillo, Edward J. ; Mazzeo, Nickolas J. ; Megdanis, Andrew C. ; Hohn, Fritz J. ; Thomson, Michael G. ; Sun, Jack
Author_Institution :
IBM T.J. Watson Res. Center, Yorktown Heights, NY, USA
fDate :
5/1/1992 12:00:00 AM
Abstract :
The full leverage offered by electron-beam lithography has been exploited in a scaled 0.25- mu m double polysilicon bipolar technology. Devices and circuits were fabricated using e-beam lithography for all mask levels with level-to-level overlays tighter than 0.06 mu m. Ion implantation was used to form a sub-100-nm intrinsic base profile, and a novel in-situ doped polysilicon emitter process was used to minimize narrow emitter effects. Transistors with 0.25- mu m emitter width have current gains above 80 and cutoff frequencies as high as 40 GHz. A record ECL gate delay of 20.8 ps at 4.82 mW has been measured together with a minimum power-delay product of 47 fJ (42.1 ps at 1.12 mW). These results demonstrate the feasibility and resultant performance leverage of aggressive scaling of conventional bipolar technologies.<>
Keywords :
bipolar integrated circuits; electron beam lithography; integrated circuit technology; 0.25 micron; 20.8 ps; 4.82 mW; 40 GHz; ECL gate delay; Si; double polysilicon bipolar technology; electron-beam lithography; in-situ doped polysilicon emitter process; ion implantation; scaling; Circuits; Cutoff frequency; Degradation; Ion implantation; Isolation technology; Lifting equipment; Lithography; Power dissipation; Silicon; Transistors;
Journal_Title :
Electron Device Letters, IEEE
