Study on the Influence of Ni2+ Doping on the Photocatalytic Performance of ZnGa2O4

The pursuit of photocatalysts is a crucial endeavor in the field of green chemistry with the growing environmental hazards caused by pollutants and organic dyes. Photocatalytic process serves as a cornerstone in addressing urgent environmental challenges, encompassing tasks such as hydrogen generation through water splitting, the reduction of pollutants, and the decomposition of organic dyes. Since d¹⁰ electronic configuration semiconductors allow higher mobility of photoexcited electrons, among them Zinc gallate has become a research hotspot because it is a typical spinel compound with two d¹⁰ configuration cations. This study specifically investigates the photocatalytic activity of ZnGa₂O₄ in the decomposition of Rhodamine B and the photolysis of water, which are critical for environmental remediation. Despite the promising potential of ZnGa₂O₄ in photocatalysis, its wide bandgap presents limitations to light absorption efficiency. In order to solve the above problems, doping Nickel ion with a + 2 charge into ZnGa₂O₄ to modify it becomes a key strategy, as it can bring additional energy levels to enhance the separation of photogenerated electron-hole pairs, which achieves the result of improving the photocatalytic efficiency, and may also lead to a wider spectral response range and improve the photocatalytic performance of the material in the visible region. Although the relevant research reports on ZnGa₂O₄ are beginning to take shape, further exploration is still needed, especially regarding the shortening of the ZnGa₂O₄ bandgap width, with detailed mechanistic insights presented. This study addresses this issue by providing a comprehensive analysis. Ni²⁺-doped ZnGa₂O₄ photocatalytic materials were prepared hydrothermally. The characterization technique to confirm the enhanced inherent photocatalytic properties of ZnGa₂O₄ is then further explained. Finally, an overview of the main challenges facing the field is given and potential directions for future research are highlighted.

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