Nanometer-scale Si selective epitaxial growth on Si(001) surfaces using the thermal decomposition of ultrathin oxide films
- 26 May 1997
- journal article
- Published by AIP Publishing in Applied Physics Letters
- Vol. 70 (21) , 2807-2809
- https://doi.org/10.1063/1.119065
Abstract
Nanometer-scale Si crystals were produced by selective epitaxial growth on Si(001) surfaces passivated with 0.3-nm-thick oxide films. Window areas for the growth were provided by void formation during the thermal decomposition of the oxide films. Dynamical processes of the void formation and epitaxial growth were observed at 630–730 °C by scanning tunneling microscopy. The crystal shape was a quadrangular pyramid and the typical size was 20 nm in length and 0.8 nm in height. The thin oxide films were found to act as masks for the selective epitaxial growth of nanoscale structures.Keywords
This publication has 15 references indexed in Scilit:
- Nucleation along step edges during Si epitaxial growth on the Si(111) surface observed by STMSurface Science, 1997
- Thermal decomposition of ultrathin oxide layers on Si(111) surfaces mediated by surface Si transportApplied Physics Letters, 1997
- Development of a multifunctional surface analysis system based on a nanometer scale scanning electron beam: Combination of ultrahigh vacuum-scanning electron microscopy, scanning reflection electron microscopy, Auger electron spectroscopy, and x-ray photoelectron spectroscopyReview of Scientific Instruments, 1996
- Structures of Steps and Appearances of {311} Facets on Si(100) SurfacesPhysical Review Letters, 1995
- Interaction of a relaxing system with a dynamical environmentPhysical Review E, 1993
- The interaction of molecular and atomic oxygen with Si(100) and Si(111)Surface Science Reports, 1993
- Growth anisotropy observed on Si(001) surfaces during Si-GSMBE using disilaneSurface Science, 1992
- Si(001) growth dynamics during Si GSMBE from disilaneSurface Science, 1992
- Stabilities of single-layer and bilayer steps on Si(001) surfacesPhysical Review Letters, 1987
- Kinetics of high-temperature thermal decomposition of SiO2 on Si(100)Journal of Vacuum Science & Technology A, 1987