Tight-binding Green’s-function approach to off-center defects: Nitrogen and oxygen in silicon
- 15 June 1986
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review B
- Vol. 33 (12) , 8188-8195
- https://doi.org/10.1103/physrevb.33.8188
Abstract
We describe a new tight-binding Green’s-function approach to defects in semiconductors which is expected to be particularly appropriate for off-center and aggregate systems. The universal two-center-integral expressions used in the tight-binding parametrization provide the mechanism for producing the appropriate Green’s-function input for any impurity position. The method is tested here for off-center substitutional nitrogen and oxygen in silicon where we produce single-particle electronic structures and localizations. We discuss these computational results, strengths, and shortcomings of the method, and potential improvements.Keywords
This publication has 47 references indexed in Scilit:
- Hydrogen-acceptor pairs in silicon: Pairing effect on the hydrogen vibrational frequencyPhysical Review B, 1985
- Substitutional oxygen-oxygen pair in siliconPhysical Review B, 1985
- Theory of off-center impurities in silicon: Substitutional nitrogen and oxygenPhysical Review B, 1984
- Electronic structure of hydrogen- and alkali-metal-vacancy complexes in siliconPhysical Review B, 1984
- Theoretical Study of the Si‐A CentrePhysica Status Solidi (b), 1980
- The electronic structure of impurities and other point defects in semiconductorsReviews of Modern Physics, 1978
- Electronic states of simple-transition-metal impurities in siliconPhysical Review B, 1977
- Localized description of the electronic structure of covalent semiconductors. II. Imperfect crystalsJournal of Physics C: Solid State Physics, 1975
- Localized description of the electronic structure of covalent semiconductors. I. Perfect crystalsJournal of Physics C: Solid State Physics, 1975
- Molecular-Orbital Treatment for Deep Levels in Semiconductors: Substitutional Nitrogen and the Lattice Vacancy in DiamondPhysical Review B, 1973