Oxygen Vacancy in ZnO-\(w\) Phase: Pseudohybrid Hubbard Density Functional Study

The study of zinc oxide, within the homogeneous electron gas approximation, results in overhybridization of zinc \(3d\) shell with oxygen \(2p\) shell, a problem shown for most transition metal chalcogenides. This problem can be partially overcome by using LDA+\(U\) (or, GGA+\(U\)) methodology. Howe...

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Bibliographic Details
Published in:arXiv.org 2020-05
Main Authors: Vrubel, Ivan I, Pervishko, Anastasiia A, Yudin, Dmitry, Sanyal, Biplab, Eriksson, Olle, Rodnyi, Piotr A
Format: Article
Language:English
Subjects:
Computer simulation
Conduction bands
Current carriers
Density
Electron gas
Electronic structure
Energy gap
Lattice parameters
Lattice vacancies
Mathematical analysis
Oxygen
Transition metal compounds
Zinc oxide
Zinc oxides
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Summary:The study of zinc oxide, within the homogeneous electron gas approximation, results in overhybridization of zinc \(3d\) shell with oxygen \(2p\) shell, a problem shown for most transition metal chalcogenides. This problem can be partially overcome by using LDA+\(U\) (or, GGA+\(U\)) methodology. However, in contrast to the zinc \(3d\) orbital, Hubbard type correction is typically excluded for the oxygen \(2p\) orbital. In this work, we provide results of electronic structure calculations of an oxygen vacancy in ZnO supercell from ab initio perspective, with two Hubbard type corrections, \(U_{\mathrm{Zn}-3d}\) and \(U_{\mathrm{O}-2p}\). The results of our numerical simulations clearly reveal that the account of \(U_{\mathrm{O}-2p}\) has a significant impact on the properties of bulk ZnO, in particular the relaxed lattice constants, effective mass of charge carriers as well as the bandgap. For a set of validated values of \(U_{\mathrm{Zn}-3d}\) and \(U_{\mathrm{O}-2p}\) we demonstrate the appearance of a localized state associated with the oxygen vacancy positioned in the bandgap of the ZnO supercell. Our numerical findings suggest that the defect state is characterized by the highest overlap with the conduction band states as obtained in the calculations with no Hubbard-type correction included. We argue that the electronic density of the defect state is primarily determined by Zn atoms closest to the vacancy.
ISSN:2331-8422
DOI:10.48550/arxiv.1909.09185