Two dimensional submicron MOSFET simulation using generalized expansion method and fixed point iteration technique to the Boltzmann transport equation

Author

Wu, Y.J. ; Hennacy, K. ; Goldsman, N. ; Mayergoyz, I.

Author_Institution

SGS-Thomson Microelectron. Inc., Carrollton, TX, USA

fYear

1995

fDate

31 May-2 Jun 1995

Firstpage

122

Lastpage

126

Abstract

2D MOSFET simulation is performed by direct solution of the Boltzmann equation. This method is based on a new generalized formulation of the Boltzmann equation which uses a spherical harmonic expansion to arbitrarily high order. The new formulation takes advantage of special properties of spherical harmonics to reduce the dimensionality of the problem, as well as facilitates analytical evaluation of the collision integral. This form is then solved using a fixed point SOR iterative technique, which avoids direct solution of large matrix equations. 2D MOSFET simulations provide the distribution function for the entire device, as well as average quantities including electron temperature, average velocity, and carrier concentration

Keywords

Boltzmann equation; MOSFET; carrier density; harmonics; iterative methods; semiconductor device models; simulation; 2D MOSFET simulation; Boltzmann transport equation; average velocity; carrier concentration; collision integral; distribution function; electron temperature; fixed point iteration technique; generalized expansion method; spherical harmonic expansion; submicron MOSFET simulation; two dimensional simulation; Boltzmann equation; Distribution functions; Educational institutions; Electrons; Harmonic analysis; Hot carriers; Integral equations; MOSFET circuits; Microelectronics; Monte Carlo methods;

fLanguage

English

Publisher

ieee

Conference_Titel

VLSI Technology, Systems, and Applications, 1995. Proceedings of Technical Papers. 1995 International Symposium on

Conference_Location

Taipei

ISSN

1524-766X

Print_ISBN

0-7803-2773-X

Type

conf

DOI

10.1109/VTSA.1995.524646

Filename

524646