Title :
Physics-based analytical model of nanowire tunnel-FETs
Author :
Gnani, Elena ; Gnudi, A. ; Reggiani, S. ; Baccarani, G.
Author_Institution :
DEIS, Univ. of Bologna, Bologna, Italy
fDate :
Oct. 29 2012-Nov. 1 2012
Abstract :
In this work we propose a physics-based analytical model of nanowire tunnel FETs, which is meant to provide a fast tool for an optimized device design. The starting point of the model is the Landauer expression of the current for 1D physical systems, augmented with suitable expressions of the tunneling probability across the tunnel junctions and the whole channel. So doing, we account for the ambipolar effect, as well as for the tunnel-related leakage current, which becomes appreciable when small band-gap materials are used. The model is validated by comparison with numerical simulation results provided by the kp technique.
Keywords :
field effect transistors; nanowires; numerical analysis; probability; semiconductor junctions; 1D physical systems; Landauer expression; ambipolar effect; band-gap materials; k·p technique; nanowire tunnel-FET; numerical simulation; optimized device design; physics-based analytical model; tunnel junctions; tunnel-related leakage current; tunneling probability; Analytical models; Doping; FETs; Junctions; Logic gates; Photonic band gap; Tunneling;
Conference_Titel :
Solid-State and Integrated Circuit Technology (ICSICT), 2012 IEEE 11th International Conference on
Conference_Location :
Xi´an
Print_ISBN :
978-1-4673-2474-8
DOI :
10.1109/ICSICT.2012.6467929
