A recent developments in Ag3VO4 based photocatalysts towards environmental remediation: Properties, synthesis, strategies and applications

光催化 光降解 材料科学 异质结 钒酸铋 纳米技术 降级(电信) 可见光谱 带隙 催化作用 化学 计算机科学 光电子学 有机化学 电信
作者
Akanksha Chauhan,Sonu Sonu,Pankaj Raizada,Pardeep Singh,Tansir Ahamad,Van‐Huy Nguyen,Quyet Van Le,Aftab Aslam Parwaz Khan,Naveen Kumar,Anita Sudhaik,Chaudhery Mustansar Hussain
出处
期刊:Journal of Industrial and Engineering Chemistry [Elsevier BV]
卷期号:130: 25-53 被引量:44
标识
DOI:10.1016/j.jiec.2023.09.042
摘要

In the last decades, the emission of heavy metals and organic pollutants into water bodies is increasing tremendously. The semiconductor-based photocatalysis is an effective technique to resolve major environmental issues. Recently, silver vanadate (Ag3VO4) based photocatalysts are gaining more attention in the research field due to its narrow bandgap (∼2.20 eV) and extended visible light absorption via Ag NPs exhibiting SPR effect. The Ag3VO4 exhibits good photocatalytic properties hence it is considered as an efficient photocatalyst for environmental remediations. The current review demonstrated the structural and optoelectronic properties of Ag3VO4 through a theoretical perspective. The first principal computation was exploited to confirm the band's optoelectronic properties and structural properties. In this review, the various synthesis methods to fabricate Ag3VO4 photocatalyst have been illustrated briefly. Also, the numerous modification ways are adapted to boost up the photocatalytic activity of Ag3VO4 are conventional heterojunction, p-n heterojunction, Z-scheme, and S-scheme. These modification strategies minimize the rate of EHP recombination and boost the charge transference and separation efficacy. Furthermore, photocatalytic applications like dye degradation, antibiotic degradation, heavy metal ions reduction, and phenol degradation over Ag3VO4 photocatalyst have been highlighted along with their respective photodegradation mechanism. Conclusively, the review summarized challenges and future emerging perspectives of Ag3VO4 photocatalyst with a conclusion for water treatment.
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