DocumentCode
1734341
Title
Nanometer ballistic MOSFET´S: Modeling, simulation and applications of digital circuits
Author
EL-Muradi, Mustafa M. ; Alla, Khalf Alla A Khalf ; Shanab, Walid T.
Author_Institution
Al Fatah Univ., Tripoli, Libya
fYear
2010
Firstpage
1
Lastpage
6
Abstract
An accurate new and simple numeral modeling of nano-scale dual gate n- MOSFET device in the ballistic region is presented. The model and the analysis is performed with channel length below 20 nm where electron transport is predominantly ballistic. In this paper a new developed modeling approach based on Boltzmann transport equation and Poisson equation in an n-channel nanoscale double-gate MOSFET is provided. The implications of ballistic transport to modeling a nanoscale MOSFET based on moment-based macroscopic transport models are discussed. The results show that the decrease in channel length toward 20nm and below increases the device performance. As it depends on the oxide thickness and the channel doping these characteristics make DG.MOSFET potentially suitable for logic- and digital circuits. The model has been implemented in the circuit simulation techniques such as Ring oscillators, CMOS inverters and other low power digital circuits.
Keywords
Boltzmann equation; MOSFET; Poisson equation; ballistic transport; circuit simulation; digital circuits; nanoelectronics; semiconductor device models; Boltzmann transport equation; Poisson equation; digital circuit; dual gate MOSFET; logic circuit; nanometer ballistic MOSFET; Approximation methods; Ballistic transport; Integrated circuit modeling; Logic gates; MOSFET circuits; Numerical models; Semiconductor device modeling; Device modeling; Digital circuit simulation; Electron Ballistic transport; Fermi Dirac Integral; Nanometer MOSFET´S; Numerical Analysis;
fLanguage
English
Publisher
ieee
Conference_Titel
Symbolic and Numerical Methods, Modeling and Applications to Circuit Design (SM2ACD), 2010 XIth International Workshop on
Conference_Location
Gammath
Print_ISBN
978-1-4244-6816-4
Type
conf
DOI
10.1109/SM2ACD.2010.5672358
Filename
5672358
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