Preparation of hollow nanospheres g-C3N4 loaded by Keggin type Cu mono-substituted heteropoly acid with enhanced visible-light harvesting and electron transfer properties for high-efficiency photocatalysis

Phosphorus Sulfur and Silicon and The Related Elements Pub Date : 2020-05-03 DOI:10.1080/10426507.2019.1700412

Tianfeng Cai, Yueru Tian, Jie Zhang

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引用次数: 4

Abstract

Abstract A series of heterojunction catalysts (CuCN-X) were successfully fabricated by loading the different amounts of Keggin type Cu mono-substituted heteropoly acid (HPW11Cu) on the surface of hollow nanospheres g-C3N4 (HSCN). The HSCNs were prepared by using SiO2 as a hard template. The chemical structure, porosity, morphology and electronic property of the prepared catalysts were investigated using XRD, SEM, N2-absorption isotherm and XPS. The results indicated that the modified HSCN show prominent absorption in the visible light range and decrease the band gap. The greatly enhanced photocatalytic activity of obtained CuCN-X have been shown by the degradation of Rhodamine B (RhB), reduction of CO2 and production of photocatalytic hydrogen under visible light irradiation. More significantly, CuCN-15 has shown significantly improved photocatalytic performance at 4.5, 3.5 and 3.3 times higher that of than HSCN for the degradation of RhB, reduction of CO2 and production of photocatalytic hydrogen, respectively. Furthermore, the mechanism for the enhanced photocatalytic activity of CuCN-X is proposed to be due to the formation of heterojunction. The electrons can be rapidly transferred from HSCN to HPW11Cu, in which facilitate charge separation and charge transfer. Graphical Abstract

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Keggin型铜单取代杂多酸负载中空纳米球g-C3N4的制备具有增强可见光捕获和电子转移性能的高效光催化

摘要通过在空心纳米球g-C3N4 (HSCN)表面负载不同量的Keggin型铜单取代杂多酸(HPW11Cu)，成功制备了一系列异质结催化剂(CuCN-X)。以SiO2为硬模板制备hscn。采用XRD、SEM、n2吸附等温线和XPS对催化剂的化学结构、孔隙率、形貌和电子性能进行了表征。结果表明，改性后的HSCN在可见光范围内具有明显的吸收，并减小了带隙。在可见光照射下，CuCN-X对罗丹明B (Rhodamine B, RhB)的降解、CO2的还原以及光催化氢的生成，表明其光催化活性大大增强。更重要的是，ccucn -15在降解RhB、还原CO2和光催化制氢方面的光催化性能分别是HSCN的4.5倍、3.5倍和3.3倍。此外，CuCN-X光催化活性增强的机理可能与异质结的形成有关。电子可以从HSCN快速转移到HPW11Cu上，有利于电荷分离和电荷转移。图形抽象

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Phosphorus Sulfur and Silicon and The Related Elements

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