Title :
A molecular dynamics simulation of ultrathin oxide films on silicon: Growth by thermal O atoms and sputtering by 100 eV Ar+ ions
Author :
Kubota, Alison ; Economou, Demeter J.
Author_Institution :
Plasma Process. Lab., Houston Univ., TX, USA
fDate :
10/1/1999 12:00:00 AM
Abstract :
Molecular dynamics was applied to study the growth and sputtering of ultrathin oxide films on (100) Si surfaces. A multibody potential which stabilized the Si/SiO2 interface was used for this purpose. Oxide growth by exposure to O atoms was found to follow Langmuir-type kinetics with unity initial sticking coefficient of O and saturation coverage of around four monolayers, in agreement with experimental data. Sputtering of an ultrathin oxide film on silicon by 100 eV Ar+ ions was simulated to study ion-assisted surface cleaning. Ion irradiation was found to promote restructuring of the surface into oxide islands, as observed experimentally. Island formation was accompanied with an increase in surface roughness. The evolution of the surface state with ion dose was predicted quantitatively
Keywords :
atom-surface impact; digital simulation; ion-surface impact; molecular dynamics method; monolayers; silicon; sputtering; surface cleaning; 100 eV; Ar; Ar+ ions; Langmuir-type kinetics; O; O atoms; Si; Si/SiO2 interface stabilisation; exposure; initial sticking coefficient; ion dose; ion irradiation; ion-assisted surface cleaning; molecular dynamics simulation; multibody potential; oxide growth; oxide islands; saturation coverage; silicon; sputtering; surface restructuring; surface roughness; surface state evolution; thermal O atoms; ultrathin oxide film; ultrathin oxide films; Annealing; Argon; Plasma temperature; Rough surfaces; Semiconductor films; Silicon; Sputtering; Surface cleaning; Surface roughness; Surface topography;
Journal_Title :
Plasma Science, IEEE Transactions on
