Journal
JOURNAL OF SOL-GEL SCIENCE AND TECHNOLOGY
Volume 103, Issue 3, Pages 691-703Publisher
SPRINGER
DOI: 10.1007/s10971-022-05875-0
Keywords
ZnO; V-doped ZnO; Spray pyrolysis; Surface roughness; Vickers microhardness
Categories
Funding
- Laboratory of Theory and Simulation of Materials (LTSM) Facility
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Vanadium-doped zinc oxide thin films were prepared by spray pyrolysis process to improve the electron mobility. The films were characterized to study their structural, morphological, chemical, optical, and mechanical properties. The results showed that the doped films had a polycrystalline hexagonal wurtzite structure, and the particle size increased with the increase of vanadium load. The distribution of zinc, oxygen, and vanadium elements was found to be constant throughout the film thickness.
Aluminum doped zinc oxides show a high electrical conductivity owing to their high electron concentration in the conduction band, which significantly hinders the development of p-n junction due to the formation of degenerate states. To overcome this limitation, it is proposed to improve the electron mobility rather than the free electron concentration. For this specific aspect, vanadium appears to be one of the most suited alternatives as a doping element. In this work, we report on the preparation of ZnO and vanadium-doped ZnO thin films by spray pyrolysis process. Vanadium loads were varied from 0 to 4 at.% in the ZnO films and its effect on the structural, morphological, chemical, optical, and mechanical properties of the fabricated thin films was investigated through a bench of characterizations techniques, including X-ray diffraction (XRD), atomic force microscope (AFM), X-ray photoelectron spectroscope (XPS), time-of-flight secondary ion mass spectroscopy (TOF-SIMS), UV-Vis spectrophotometer, and digital Vickers microhardness tester. The obtained results demonstrate the successful formation of pristine ZnO films and V-doped ZnO, which were found to be polycrystalline with a hexagonal wurtzite crystal structure. According to the self-correlation function, AFM images reveal that the particle size increases with respect to the V-load. TOF-SIMS analyses confirm the constant distribution of Zn, O and V elements throughout the film thickness. Moreover, our films are found to be optically transparent in the 400-1200 nm range with associated band gaps energy ranging from 3.18 to 3.26 eV. Finally, mechanical measurements have been carried out using a conventional diamond-pyramidal-indenter Vickers test. The results confirmed that by increasing V concentration, the microhardness increases. [GRAPHICS]
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