A Generalized Drift-Diffusion Model for Rectifying Schottky Contact Simulation

Author

Traversa, Fabio Lorenzo ; Bertazzi, Francesco ; Bonani, Fabrizio ; Guerrieri, Simona Donati ; Ghione, Giovanni ; Pérez, Susana ; Mateos, Javier ; González, Tomás

Author_Institution

Dept. d´´Eng. Electron., Univ. Autonoma de Barcelona, Barcelona, Spain

Volume

57

Issue

7

fYear

2010

fDate

7/1/2010 12:00:00 AM

Firstpage

1539

Lastpage

1547

Abstract

We present a discussion on the modeling of Schottky barrier rectifying contacts (diodes) within the framework of partial-differential-equation-based physical simulations. We propose a physically consistent generalization of the drift-diffusion model to describe the boundary layer close to the Schottky barrier where thermionic emission leads to a non-Maxwellian carrier distribution, including a novel boundary condition at the contact. The modified drift-diffusion model is validated against Monte Carlo simulations of a GaAs device. The proposed model is in agreement with the Monte Carlo simulations not only in the current value but also in the spatial distributions of microscopic quantities like the electron velocity and concentration.

Keywords

Monte Carlo methods; Schottky barriers; gallium arsenide; partial differential equations; GaAs; GaAs device; Monte Carlo simulation; Schottky barrier; Schottky contact simulation; boundary condition; drift-diffusion model; electron concentration; electron velocity; non-Maxwellian carrier distribution; partial-differential-equation-based physical simulation; thermionic emission; Boundary conditions; Electrons; Partial differential equations; Radiative recombination; Schottky barriers; Schottky diodes; Semiconductor diodes; Spontaneous emission; Surface treatment; Thermionic emission; Schottky barriers; semiconductor device modeling;

fLanguage

English

Journal_Title

Electron Devices, IEEE Transactions on

Publisher

ieee

ISSN

0018-9383

Type

jour

DOI

10.1109/TED.2010.2047909

Filename

5462889