DocumentCode
1217417
Title
Modeling and optimization of fringe capacitance of nanoscale DGMOS devices
Author
Bansal, Aditya ; Paul, Bipul C. ; Roy, Kaushik
Author_Institution
Sch. of Electr., Purdue Univ., West Lafayette, IN, USA
Volume
52
Issue
2
fYear
2005
Firstpage
256
Lastpage
262
Abstract
We analyze the impact of gate electrode thickness and gate underlap on the fringe capacitance of nanoscale double-gate MOS (DGMOS) transistors. We propose an analytical fringe capacitance model considering gate underlap and finite source/drain length. A comparison with the simulation results show that the model can accurately estimate the fringe capacitance of the device. We show that an optimum gate underlap can significantly reduce the fringe capacitance resulting in higher performance and lower power consumption. Also, the effects of process variation in gate underlap devices are discussed. Simulation results on a three-stage ring oscillator show that with optimum gate underlap 32% improvement in delay can be achieved.
Keywords
MOSFET; capacitance; nanoelectronics; semiconductor device models; conformal mapping; delay improvement; double-gate MOS transistors; double-gate MOSFET; finite source-drain length; fringe capacitance model; gate electrode thickness; gate underlap devices; nanoscale DGMOS devices; optimization; optimum gate underlap; power consumption; process variation; three-stage ring oscillator; Analytical models; Delay; Electrodes; Energy consumption; Immune system; MOSFET circuits; Nanoscale devices; Parasitic capacitance; Ring oscillators; Silicon;
fLanguage
English
Journal_Title
Electron Devices, IEEE Transactions on
Publisher
ieee
ISSN
0018-9383
Type
jour
DOI
10.1109/TED.2004.842713
Filename
1386595
Link To Document