Properties of amorphous GaN from first-principles simulations

B. Cai; D. A. Drabold

doi:10.1103/PhysRevB.84.075216

Properties of amorphous GaN from first-principles simulations

B. Cai, D. A. Drabold

Research output: Contribution to journal › Article › peer-review

26 Scopus citations

Abstract

Amorphous GaN (a-GaN) models are obtained from first-principles simulations. We compare four a-GaN models generated by "melt-and- quench" and the computer alchemy method. We find that most atoms tend to be fourfold, and a chemically ordered continuous random network is the ideal structure for a-GaN albeit with some coordination defects. Where the electronic structure is concerned, the gap is predicted to be less than 1.0 eV, underestimated as usual by a density functional calculation. We observe a highly localized valence tail and a remarkably delocalized exponential conduction tail in all models generated. Based upon these results, we speculate on potential differences in n- and p-type doping. The structural origin of tail and defect states is discussed. The vibrational density of states and dielectric function are computed and seem consistent with experiment.

Original language	English (US)
Article number	075216
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	84
Issue number	7
DOIs	https://doi.org/10.1103/PhysRevB.84.075216
State	Published - Aug 15 2011
Externally published	Yes

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Condensed Matter Physics

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10.1103/PhysRevB.84.075216

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abstract = "Amorphous GaN (a-GaN) models are obtained from first-principles simulations. We compare four a-GaN models generated by {"}melt-and- quench{"} and the computer alchemy method. We find that most atoms tend to be fourfold, and a chemically ordered continuous random network is the ideal structure for a-GaN albeit with some coordination defects. Where the electronic structure is concerned, the gap is predicted to be less than 1.0 eV, underestimated as usual by a density functional calculation. We observe a highly localized valence tail and a remarkably delocalized exponential conduction tail in all models generated. Based upon these results, we speculate on potential differences in n- and p-type doping. The structural origin of tail and defect states is discussed. The vibrational density of states and dielectric function are computed and seem consistent with experiment.",

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N2 - Amorphous GaN (a-GaN) models are obtained from first-principles simulations. We compare four a-GaN models generated by "melt-and- quench" and the computer alchemy method. We find that most atoms tend to be fourfold, and a chemically ordered continuous random network is the ideal structure for a-GaN albeit with some coordination defects. Where the electronic structure is concerned, the gap is predicted to be less than 1.0 eV, underestimated as usual by a density functional calculation. We observe a highly localized valence tail and a remarkably delocalized exponential conduction tail in all models generated. Based upon these results, we speculate on potential differences in n- and p-type doping. The structural origin of tail and defect states is discussed. The vibrational density of states and dielectric function are computed and seem consistent with experiment.

AB - Amorphous GaN (a-GaN) models are obtained from first-principles simulations. We compare four a-GaN models generated by "melt-and- quench" and the computer alchemy method. We find that most atoms tend to be fourfold, and a chemically ordered continuous random network is the ideal structure for a-GaN albeit with some coordination defects. Where the electronic structure is concerned, the gap is predicted to be less than 1.0 eV, underestimated as usual by a density functional calculation. We observe a highly localized valence tail and a remarkably delocalized exponential conduction tail in all models generated. Based upon these results, we speculate on potential differences in n- and p-type doping. The structural origin of tail and defect states is discussed. The vibrational density of states and dielectric function are computed and seem consistent with experiment.

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Properties of amorphous GaN from first-principles simulations

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