Enhanced photocatalytic performance of Bi-doped TiO₂ under sunlight and UV light: mechanistic insights and comparative analysis.

IF 2.7 3区化学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY

Photochemical & Photobiological Sciences Pub Date : 2024-08-01 Epub Date: 2024-07-15 DOI:10.1007/s43630-024-00609-3

Saurav Mishra, Nandana Chakinala, Govind Sethia, Anand G Chakinala, Praveen K Surolia

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Abstract

Bismuth-doped metal oxides exhibit favourable photocatalytic features when exposed to both sunlight and UV light. In this approach, Bi⁰/TiO₂ and Bi⁺³/TiO₂ photocatalysts were prepared and their structural and optical properties are analysed using various characterization techniques. These developed photocatalysts were further tested for the photocatalytic elimination of Nitrobenzene in UV light and sunlight and compared with the performance of bare TiO₂. The catalyst Bi⁺³/TiO₂ performed better in UV light with 72.31% degradation, and 4.74 × 10^-6 mol.litre^-1.min^-1 initial rate of reaction. However, when exposed to sunlight, Bi⁰/TiO₂ outperformed with 73.85% degradation, and 4.63 × 10^-6 mol.min^-1 initial rate of reaction. This significant increase in photocatalytic activity of Bi⁰/TiO₂ under sunlight could be accredited to increased light harvesting and enhanced efficiency in charge carrier separation, both of which were made possible by bismuth-induced surface plasmon resonance.

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双掺杂二氧化钛在阳光和紫外线下的光催化性能增强：机理认识和比较分析。

掺铋金属氧化物在阳光和紫外线的照射下都能表现出良好的光催化特性。在这种方法中，制备了 Bi0/TiO2 和 Bi+3/TiO2 光催化剂，并使用各种表征技术分析了它们的结构和光学特性。这些开发的光催化剂在紫外线和阳光下进行了光催化消除硝基苯的进一步测试，并与裸 TiO2 的性能进行了比较。催化剂 Bi+3/TiO2 在紫外线下的性能更好，降解率为 72.31%，初始反应速率为 4.74 × 10-6 mol.litre-1.min-1。然而，当暴露在阳光下时，Bi0/TiO2 的性能更好，降解率为 73.85%，初始反应速率为 4.63 × 10-6 摩尔.升-1。在阳光下，Bi0/TiO2 的光催化活性大幅提高，这可能是因为双铋诱导的表面等离子体共振提高了光收集能力和电荷载流子分离效率。

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