Summary: | In this study, Nb2O5-ZnO films were synthesized using a two-step process that involved growing hydrothermal ZnO microrods on the surface of anodized nanoporous Nb2O5. We present the morphological, structural, and optical properties of Nb2O5-ZnO films synthesized in hydrothermal solutions with varying concentrations of Zinc Acetate ranging from 0.01 to 0.25 M, as well as the photocatalytic performance of each sample. The results show that ZnO grew in the form of rods from 0.01 to 0.05 M and then began to form hexagonal prisms at 0.25 M molar concentration. The XRD patterns of the Nb2O5-ZnO films clearly show a dominant orthorhombic Nb2O5 phase as well as a ZnO phase with a hexagonal wurtzite structure. Another finding from this study is that as molar concentration increases, the band gap of the Nb2O5-ZnO film decreases from 3.077 to 3.017 eV. Owing to high surface area and porosity of the produced films, visible light-assisted photocatalytic activity of Methylene Blue solution was performed to examine the performance of the films on dye degradation. The obtained results confirmed that the sample Nb2O5-ZnO 0.05 M showed the highest photocatalytic activity, with almost 98.41% removal of Methylene Blue after 180 min under the light exposure. The excellent photocatalytic performance of Nb2O5-ZnO 0.05M is expected due to the high effective surface area for Methylene Blue reaction, good crystallinity, high absorption, and low band gap behaviour of the sample. Furthermore, the couple layer can significantly reduce the recombination rate of photogenerated electron-hole pairs while also compensating for the disadvantages of the individual components, resulting in a synergistic effect of efficient charge separation and improved photostability. © 2023, King Fahd University of Petroleum & Minerals.
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