Ab initio study of symmetric tilt boundaries in ZnO
Abstract
The atomic and electronic structure of the [0001]/(1¯ 2¯ 3 0) Σ=7 symmetric tilt boundary in ZnO has been investigated by an ab initio plane-wave pseudopotential method within the local-density approximation. Two types of equilibrium geometries are obtained with similar boundary energies. Atomic arrangement is largely reconstructed to vanish dangling bonds in one configuration, whereas the other shows small bond distortion but has dangling bonds at the boundary core. The balance between the energies for deforming atomic arrangements and vanishing dangling bonds should be significant in determining the boundary energies. The electronic structure of the grain boundaries is discussed with a special interest in the relationship with the bond disorder. Owing to the bond distortion and/or the presence of the dangling bonds, localized states form mainly at the lower valence band and the bottom of the upper valence band. On the other hand, the electronic states in the vicinity of the band gap are not significantly affected by the bond disorder. Deep electronic states are not generated in the band gap even for the configuration with dangling bonds. This behavior can be generally explained by the band structure intrinsic to ZnO.
- Publication:
-
Physical Review B
- Pub Date:
- January 2001
- DOI:
- 10.1103/PhysRevB.63.045410
- Bibcode:
- 2001PhRvB..63d5410O
- Keywords:
-
- 73.20.Hb;
- 71.20.Nr;
- 68.35.Ct;
- Impurity and defect levels;
- energy states of adsorbed species;
- Semiconductor compounds;
- Interface structure and roughness