Quantum confinement effect on defect level of hydrogen doped rutile VO2 nanowires

Accurate description of solubility and defect ionization energies in low dimensional nanostructures is critical for electronic applications of semiconductors with improved functionalities. Here, we present quantum confinement effect driven strategies for tuning defect level of hydrogen doping in the...

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Bibliographic Details
Published in:Journal of applied physics 2022-06, Vol.131 (23)
Main Authors: Dey, Manoj, Chowdhury, Suman, Kumar, Sonu, Kumar Singh, Abhishek
Format: Article
Language:English
Subjects:
Diameters
Doping
Hydrogen
Ionization
Nanostructured materials
Nanowires
Quantum confinement
Rutile
Vanadium oxides
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Summary:Accurate description of solubility and defect ionization energies in low dimensional nanostructures is critical for electronic applications of semiconductors with improved functionalities. Here, we present quantum confinement effect driven strategies for tuning defect level of hydrogen doping in the core region of rutile VO 2(R) nanowires. The inverse dependence of a bandgap with a diameter ( ∝ d − 0.48) confirms the presence of quantum confinement effect in nanowires. The hydrogen doping in both interstitial and substitution at the O site behaves as a deep donor in low diameter nanowires, where the effect of quantum confinement is significant. The position of a donor charge transition level becomes increasingly shallower with increased nanowire diameters. The ionization energies of hydrogen defects decrease for larger-diameter nanowires due to the dielectric screening effect increment. This indicates the possibility of achieving n-type dopability with large diameter VO 2(R) nanowires. This study prescribes the strategies for optimizing doping and the defect level for extensive applications of highly correlated 1D nanostructured materials.
ISSN:0021-8979
1089-7550
DOI:10.1063/5.0095834