Title :
An Analytic Model to Account for Quantum–Mechanical Effects of MOSFETs Using a Parabolic Potential Well Approximation
Author :
He, Jin ; Chan, Mansun ; Zhang, Xing ; Wang, Yangyuan
Author_Institution :
Sch. of Electron. Eng. & Comput. Sci., Peking Univ., Beijing
Abstract :
An analytic model to account for the quantum-mechanical effects (QMEs) of the MOSFETs using a parabolic potential well approximation is presented in this paper. Based on the solution of the coupled Schroumldinger and Poisson equations following the Wentzel-Kramer-Brillouin method, a transcendental equation of the subband energy level has been rigorously derived to obtain an approximate analytic solution for the subband energy levels and the inversion charge centroid. Calculated results from the obtained analytical solution are compared with the previous approximate solutions reported in the literature and the numerically simulated data. A good agreement between the analytical and numerical is obtained, proving the validity of the analytic modeling of QMEs
Keywords :
MOSFET; Poisson equation; Schrodinger equation; approximation theory; energy states; parabolic equations; quantum theory; semiconductor device models; MOSFET; Poisson equations; QME; Schrodinger equations; Wentzel-Kramer-Brillouin method; inversion charge centroid; parabolic potential well approximation; quantum-mechanical effects; subband energy level; transcendental equation; Analytical models; Dielectric substrates; Energy states; Helium; MOSFETs; Numerical simulation; Poisson equations; Potential well; Quantum mechanics; Very large scale integration; Device physics; MOSFETs; quantum–mechanical effects (QMEs); very large scale integration (VLSI);
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2006.880359
