Efficient Ni and Fe doping process in ZnO with enhanced photocatalytic activity: A theoretical and experimental investigation

Zn1-xNixO and Zn1-xFexO structures were synthesized by the microwave-assisted hydrothermal method. The best photocatalytic degradation of rhodamine B (RhB) and 4-nitrophenol (4-NP) were achieved by the Zn0.96Ni0.04O and Zn0.99Fe0.01O. The specificity of each dopant showed significance in the positions of the impurity energy levels, which ended up influencing the electron-hole separation and transport, as demonstrated by the photoluminescence emissions. The morphological analysis revealed that besides inhibiting the growth of particles, the incorporation of dopant ions into the ZnO lattice triggered a nucleation process, consequently changing their morphology. Density functional theory (DFT) calculations showed that the Fe3+ 3d orbitals generate energy levels below the conduction band (CB) while for Ni2+, the levels were found to be spread in a broad energy range above the valence band (VB). The synergistic effect of band gaps alteration, inhibition of electron-hole pair recombination and appearance of new trapping energy sites justifies the superior photocatalytic activity.

Automated summary

Zn1-xNixO and Zn1-xFexO structures synthesized by the microwave-assisted hydrothermal method showed the best photocatalytic degradation performance for RhB and 4-NP. The specific dopant positions significantly influenced the separation and transport of electron-hole pairs. Morphological analysis revealed that the incorporation of dopant ions not only inhibited particle growth but also triggered a nucleation process, leading to morphology changes.