Title :
DIBL in short-channel NMOS devices at 77 K
Author :
Deen, M. Jamal ; Yan, Z.X.
Author_Institution :
Sch. of Eng. Sci., Simon Fraser Univ., Barnaby, BC, Canada
fDate :
4/1/1992 12:00:00 AM
Abstract :
Detailed experimental and two-dimensional numerical simulation results on drain-induced barrier lowering (DIBL) versus channel length at 300 and 77 K in short-channel NMOS devices are presented. It is found that by decreasing the temperature from 300 to 77 K. DIBL in NMOS devices with effective channel lengths (L) from 0.5 to 2.0 μm is improved for the range of L<0.6 μm and L>1.2 μm, but is worse for L between 0.6 and 1.2 μm. The new version of the two-dimensional device numerical simulation program MINIMOS 4.0, which includes device modeling at cryogenic temperatures, was used to investigate this unique characteristic. The measured DIBL characteristics can be explained physically as the transition from surface DIBL through the subsurface DIBL to the bulk DIBL or punchthrough effect at 300 K, but almost a surface DIBL for the whole range of channel length variation at 77 K. Design considerations for the channel doping profile for low-temperature operation based on keeping the same DIBL and VTH as required for room-temperature operation are briefly discussed
Keywords :
CMOS integrated circuits; doping profiles; insulated gate field effect transistors; integrated circuit technology; metal-insulator-semiconductor devices; semiconductor device models; 0.5 to 2 micron; 300 K; 77 K; CMOS technology; MINIMOS 4.0; channel doping profile; channel length; device modeling; drain-induced barrier lowering; low-temperature operation; punchthrough effect; short-channel NMOS devices; two-dimensional numerical simulation; CMOS technology; Circuits and systems; Cryogenics; Doping profiles; Length measurement; MOS devices; Nitrogen; Numerical simulation; Temperature distribution; Very large scale integration;
Journal_Title :
Electron Devices, IEEE Transactions on
