Effects of oxide-charge space correlation on electron mobility in inversion layers

2 May 1994

journal article
Published by IOP Publishing in Semiconductor Science and Technology

Vol. 9 (5) , 1102-1107
https://doi.org/10.1088/0268-1242/9/5/015

Abstract

The effect of the space correlation of oxide charges on the effective mobility of electrons in the channel of an NMOS transistor has been studied. Mobility has been obtained by a single-electron Monte Carlo simulation in which space correlation has been included simultaneously with other effects such as screening of point charges by mobile carriers, image charges, and phonon and surface-roughness scattering. Results have been obtained by assuming different degrees of space correlation for several temperature values and diverse oxide-charge concentrations and positions. The charged-centre space correlation is shown to have a noticeable effect on the electron mobility.

Keywords

This publication has 15 references indexed in Scilit:

A comprehensive model for Coulomb scattering in inversion layers
Journal of Applied Physics, 1994
Simulation of linear and nonlinear electron transport in homogeneous silicon inversion layers
Solid-State Electronics, 1993
An analytical expression for phonon-limited electron mobility in silicon-inversion layers
Journal of Applied Physics, 1993
Monte Carlo study of electron transport in silicon inversion layers
Physical Review B, 1993
Monte Carlo study of electronic transport in ${Al}_{1 - x}$ ${Ga}_{x}$ As/GaAs single-well heterostructures
Physical Review B, 1986
Electronic properties of two-dimensional systems
Reviews of Modern Physics, 1982
Two-dimensional electron transport in semiconductor layers. I. Phonon scattering
Annals of Physics, 1981
Impurity and phonon scattering in layered structures
Applied Physics Letters, 1979
The scattering of electrons by surface oxide charges and by lattice vibrations at the silicon-silicon dioxide interface
Surface Science, 1972
Properties of Semiconductor Surface Inversion Layers in the Electric Quantum Limit
Physical Review B, 1967