DocumentCode
1131331
Title
Double jeopardy in the nanoscale court [MOSFET modeling]
Author
Chen, Qiang ; Bowman, Keith A. ; Harrell, Evans M. ; Meindl, James D.
Author_Institution
Microelectron. Res. Center, Georgia Inst. of Technol., Atlanta, GA, USA
Volume
19
Issue
1
fYear
2003
fDate
1/1/2003 12:00:00 AM
Firstpage
28
Lastpage
34
Abstract
Physics-based compact short-channel models of threshold voltage and subthreshold swing for undoped symmetric double-gate MOSFETs are presented, developed from analytical solutions of the two-dimensional Poisson equations in the channel region. These models accurately characterize the subthreshold and near-threshold regions of operation by appropriately including essential phenomena such as volume inversion and the dominance of mobile charges over fixed charges under threshold conditions. Explicit, analytical expressions are derived for a scale length, which results from an evanescent-mode analysis. These equations readily quantify the impact of silicon film thickness and gate oxide thickness on the minimum channel length and device characteristics and can be used as an efficient guideline for device designs. These newly developed models are exploited to make a comprehensive projection on the scaling limits of undoped double-gate MOSFETs. On the individual device level, model predictions indicate that the minimum channel length can be scaled beyond 10 nm for a turn-off behavior of S=100 mV/dec for a silicon film thickness below 5 nm and an electrical equivalent oxide thickness below 1 nm.
Keywords
MOSFET; Poisson equation; nanoelectronics; semiconductor device models; 1 nm; 10 nm; 5 nm; analytical solutions; electrical equivalent oxide thickness; evanescent-mode analysis; gate oxide thickness; gigascale integration; minimum channel length; mobile charges; scale length; scaling limits; short-channel effect suppression; short-channel models; silicon film thickness; subthreshold swing; threshold voltage; turn-off characteristics; two-dimensional Poisson equations; undoped symmetric double-gate MOSFETs; volume inversion; Dielectric thin films; Doping; Electrons; Electrostatics; MOSFET circuits; Semiconductor films; Silicon; Subthreshold current; Temperature; Threshold voltage;
fLanguage
English
Journal_Title
Circuits and Devices Magazine, IEEE
Publisher
ieee
ISSN
8755-3996
Type
jour
DOI
10.1109/MCD.2003.1175105
Filename
1175105
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