Abstract
In the present work, CuO and Cu1-xZnxO were synthesized with the function of the Zn doping ratio by microwave-assisted chemical precipitation approach. The X-ray diffraction pattern shows that the mono-phase CuO with a mono-clinical structure and no other secondary phase has been observed for the Cu1-xZnxO with different Zn ratio and confirms CuO lattice does not get destroyed by the addition of Zn. The Raman spectra and HR-TEM analysis support the XRD results. The self-assembled hierarchical flower morphology was obtained for the higher doping ratio of Zn. The energy dispersive analysis of X-ray spectrum confirms the presence of Zn in the CuO lattice and the stoichiometry obtained. The optical band gap was found to be 1.78 eV for CuO nanoparticles, and the values are between 1.80 and 2.29 eV for Zn-doped CuO. For higher Zn-doped CuO, optical band splitting was observed due to flower-like morphology. The recombination of an electron–hole was reduced for higher doping ratio nanoparticles. These properties are needed for photocatalytic application.
Highlights
At present, more attention is paid to metal oxide materials; in particular Copper (Cu) based metal oxides have various nanostructures, such as nanorods, nanoplates, and nanoflower
We investigated the impact of Zn doping, which could significantly boost photocatalytic activity
CuO and Cu1-xZnxO nanoparticles were successfully synthesized with the function of the Zn doping ratio via microwave-assisted chemical precipitation approach
Summary
More attention is paid to metal oxide materials; in particular Copper (Cu) based metal oxides have various nanostructures, such as nanorods, nanoplates, and nanoflower. CuO and Cu1 − xZnxO were synthesized with the function of the Zn doping ratio by microwave-assisted chemical precipitation approach. The optical band gap was found to be 1.78 eV for CuO nanoparticles and the values are between 1.80 and 2.29 eV for Zn doped CuO.
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