Theoretical study on group III elements and F co-doped ZnO

To realize the wide application of ZnO, one of the urgent and challenging tasks is the preparation of high-conductivity ZnO. Doping with group III elements (Al, Ga, and In) or F is adopted to achieve n-type ZnO. Their equal proportion co-doping (e.g. Al–F, Ga–F, and In–F) improves the conductivity w...

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Bibliographic Details
Published in:Journal of alloys and compounds 2020-04, Vol.819, p.153012, Article 153012
Main Authors: Ma, Jiani, Zhang, Wei, Lin, Jianyan, Sun, Yu, Ma, Jiangang, Xu, Haiyang, Liu, Yichun, Yang, Guochun
Format: Article
Language:English
Subjects:
Anions
Cations
Co-doping
Conductivity
Dopants
Doping
Electrical resistivity
First principles
Free energy
Gallium
Heat of formation
Zinc oxide
ZnO
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Summary:To realize the wide application of ZnO, one of the urgent and challenging tasks is the preparation of high-conductivity ZnO. Doping with group III elements (Al, Ga, and In) or F is adopted to achieve n-type ZnO. Their equal proportion co-doping (e.g. Al–F, Ga–F, and In–F) improves the conductivity with respect to mono-doping. Moreover, changing the doping concentration of Al and F further increases the conductivity. The physical mechanism behind the experimental phenomena has not been explored, thus far. Here, first-principles calculations were employed to explore the effect of cation-anion co-doping (Al–F, Ga–F, and In–F) and the variation of doping ratios on the geometric structure and the electron properties of ZnO. For equal proportion co-doping, the strong hybridization between the dopants in In–F induces a localized state in band gap, reducing the electrical conductivity, which is in sharp contrast with Al/Ga–F ones. Those mainly originate from the different arrangements of cation-anion dopants in the stable configurations (e.g. In and F form bond, whereas Al/Ga and F do not). Compared with Al–2F co-doping, 2Al–F can achieve the higher conductivity from the standpoint of lower defect formation energy and transition level. However, the 2In–F/2Ga–F becomes much worse with respect to 2Al–F. Our work not only rationalizes experimental observation but also provides useful information for improving the conductivity of similar binary compounds. [Display omitted] •High-conductivity ZnO is achieved via co-doping with 2Al and F.•Al–F improves the performance of ZnO, whereas In–F does not.•The arrangement of cation-anion dopants dominates the conductivity of ZnO.•Our results rationalize the experimental observations.
ISSN:0925-8388
1873-4669
DOI:10.1016/j.jallcom.2019.153012