Characterization of CuZnO Nanocomposite Thin Films Prepared from CuO–ZnO Sputtered Films

Copper oxide–zinc oxide (CuO–ZnO) thin films were prepared by a sputtering technique to examine the creation of a CuZnO thin-film nanocomposite. The base film was a zinc oxide layer. A copper oxide layer was deposited on glass coated with ZnO for different deposition times. The structure was examine...

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Bibliographic Details
Published in:Journal of electronic materials 2020-12, Vol.49 (12), p.7179-7186
Main Authors: Abdel-wahab, M. Sh, Wassel, Ahmed R., Hammad, Ahmed H.
Format: Article
Language:English
Subjects:
Absorption spectra
Characterization and Evaluation of Materials
Chemistry and Materials Science
Copper
Copper oxides
Crystallites
Deposition
Electronics and Microelectronics
Film thickness
Instrumentation
Materials Science
Morphology
Nanocomposites
Optical and Electronic Materials
Optical properties
Optical transition
Photoluminescence
Refractivity
Roughness
Solid State Physics
Spectrum analysis
Sputtered films
Thin films
Zinc oxide
Zinc oxides
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Summary:Copper oxide–zinc oxide (CuO–ZnO) thin films were prepared by a sputtering technique to examine the creation of a CuZnO thin-film nanocomposite. The base film was a zinc oxide layer. A copper oxide layer was deposited on glass coated with ZnO for different deposition times. The structure was examined by x-ray diffraction analysis. Plane (002) was detected for ZnO phase, while planes (111) and 1 ¯ 11 were detected for CuO phase. The crystallite size was calculated for both ZnO and CuO. The crystallite size of CuO phases increased with increasing deposition time, whereas the size of crystals of ZnO phase decreased. The film morphology and roughness were evaluated by scanning electron microscopy. Agglomeration of fine particles was observed. The film roughness decreased from 0.0685 nm for base ZnO films to 0.0357 nm for 800 s CuO–ZnO films. Elemental analysis of the film components was carried out by energy-dispersive x-ray spectroscopy. The ratio of O atoms remained constant at 50 at.%, while the Zn content decreased from 50% for the base sample to 27.66% for the 800 s CuO–ZnO sample. Optical properties, such as the optical absorption spectra, optical transition, and refractive index of the prepared films, were investigated. The optical transition was affected by the CuO layer and the film thickness. The optical bandgap decreased from 3.258 eV for ZnO films with thickness of 107 nm to 3.162 eV for 800 s CuO–ZnO films with thickness of 163 nm. Nonlinear optical behavior was deduced from the optical parameters, and was enhanced by the presence of CuO layers, increasing from 4.151 × 10 −11  esu for the ZnO sample to 4.434 × 10 −11  esu for the 800 s CuO–ZnO sample. The photoluminescence spectra of the films were investigated and interpreted.
ISSN:0361-5235
1543-186X
DOI:10.1007/s11664-020-08505-z