Title :
Channel length dependence of discrete dopant effects in narrow si nanowire transistors: A full 3D NEGF study
Author :
Martinez, A. ; Asenov, A. ; Aldegunde, M.
Author_Institution :
Dept of Electron. & Electr. Eng., Univ. of Glasgow, Glasgow, UK
Abstract :
In this paper we study the variability induced by random discrete dopants in a gate-all-around silicon nanowire transistor. The electron transport is described using the Non-Equilibrium Green Function formalism. Coupled-mode-space representations are used. A silicon nanowire transistor with 4.2×4.2 nm2 cross-section and two different channel lengths (6 nm and 12 nm) has been considered. The mobility associated with discrete dopants can be estimated from the averaged current voltage characteristics. The threshold voltage and subthreshold slope variability are greatly reduced in the longer channel length transistor. At the same time the on current variability associated with the resistance variability of the access regions is virtually independent of the channel length.
Keywords :
Green´s function methods; nanowires; transistors; channel length dependence; channel length transistor; coupled-mode-space representation; discrete dopant effect; electron transport; gate-all-around silicon nanowire transistor; non-equilibrium Green function formalism; resistance variability; subthreshold slope variability; threshold voltage; Electric potential; Logic gates; Nanoscale devices; Resistance; Semiconductor process modeling; Silicon; Transistors; Current varibilities; Discrete random dopants; Non Equilibrium Green Function Formalism; Silicon nanowire transistors;
Conference_Titel :
Computational Electronics (IWCE), 2010 14th International Workshop on
Conference_Location :
Pisa
Print_ISBN :
978-1-4244-9383-8
DOI :
10.1109/IWCE.2010.5677945
