Numerical simulation of the current-voltage characteristics of heteroepitaxial Schottky-barrier diodes

Author

Bhapkar, Udayan V. ; Mattauch, Robert J.

Author_Institution

Dept. of Electr. Eng., Virginia Univ., Charlottesville, VA, USA

Volume

40

Issue

6

fYear

1993

fDate

6/1/1993 12:00:00 AM

Firstpage

1038

Lastpage

1046

Abstract

A numerical model resulting in the current-voltage characteristics of standard and heteroepitaxial Schottky-barrier diodes is presented. Simulations of GaAs diodes, as well as InGaAs diodes grown on GaAs and InP substrates, are presented. The model considers quantum-mechanical tunneling, and is therefore applicable to highly doped devices. A self-consistent drifted-Maxwellian distribution is used to model the electron energy distribution at high current densities. The assumption of a drifted-Maxwellian distribution is shown to lead to higher current at high bias than predicted with the assumption of a Maxwell-Boltzmann or Fermi-Dirac distribution. The presence of a heterojunction at the InGaAs-substrate interface is predicted to lead to an additional series resistance component

Keywords

III-V semiconductors; Schottky-barrier diodes; current density; gallium arsenide; indium compounds; semiconductor device models; tunnelling; GaAs; GaAs diodes; InGaAs diodes; InP substrates; current-voltage characteristics; electron energy distribution; heteroepitaxial Schottky-barrier diodes; high current densities; highly doped devices; numerical model; quantum-mechanical tunneling; self-consistent drifted-Maxwellian distribution; series resistance component; Current-voltage characteristics; Electrons; Gallium arsenide; Indium gallium arsenide; Indium phosphide; Numerical models; Numerical simulation; Schottky diodes; Substrates; Tunneling;

fLanguage

English

Journal_Title

Electron Devices, IEEE Transactions on

Publisher

ieee

ISSN

0018-9383

Type

jour

DOI

10.1109/16.214726

Filename

214726