Study on Method of Doping Au Nanoparticles on ZnO Stratified Microstructure to Enhance Photocatalytic Ability and Antibacterial Activity

Bulletin of Chemical Reaction Engineering & Catalysis Pub Date : 2023-04-10 DOI:10.9767/bcrec.17566

Anh-Tuan Vu, Thi Anh Tuyet Pham

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引用次数: 2

Abstract

In this study, stratified microstructure gold/zinc oxide (Au/ZnO) composites were successfully prepared by the method of dispersing Au nanoparticles (Au NPs) on the surface of the hierarchical flower ZnO via HAuCl4 reduction in the presence of different reducing agents such as sodium citrate (SC), sodium borohydride (SB), sodium hydroxide and ethanol (SE), and Hg lamp 250W. Au-doped samples were named Au/ZnO-SC, Au/ZnO-SB, Au/ZnO-SE, and Au/ZnO-Hg lamp, respectively. Au/ZnO-SC and Au/ZnO-SB revealed the uniform distribution of Au nanoparticles on the ZnO substrate, meanwhile, Au nanoparticles were very densely distributed in Au/ZnO-SE and Au/ZnO-Hg lamp samples. The pure ZnO only showed an absorption peak in the ultraviolet (UV) region, Au/ZnO samples indicated additional absorption peaks in the visible light region (500-600 nm), which were characteristic of the surface plasmon resonance (SPR) effect of Au NPs in composites. Therefore, their bandgap energy was reduced compared to ZnO (3.202 eV), leading to increased photocatalytic efficiency under visible light irradiation. Among the doped samples, Au/ZnO-SC (with Au content as 5 wt%) had the largest surface area (26.23 m2/g) and the highest pore volume (0.263 cm3/g) and average pore width (33.2 nm). As a result, it showed the highest catalytic efficiency through complete degradation of tartrazine (TA) within 30 min with a reaction rate of 0.124 min−1 under Hg lamp 250 irradiation. In addition, both pure ZnO and Au/ZnO nanocomposites exhibited high antimicrobial activity in killing Escherichia coli (E. coli), and their enhancing effect of them was reliant on the weight ratio of Au on ZnO and the concentration of tested samples. These results indicated that Au/ZnO material has prominent potential for applications in water environment treatment. Copyright © 2023 by Authors, Published by BCREC Group. This is an open access article under the CC BY-SA License (https://creativecommons.org/licenses/by-sa/4.0).

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在ZnO层状结构上掺杂金纳米粒子增强光催化能力和抗菌活性的方法研究

在柠檬酸钠(SC)、硼氢化钠(SB)、氢氧化钠和乙醇(SE)等还原剂的存在下，在250W的汞灯下，通过HAuCl4还原将Au纳米粒子(Au NPs)分散在层次花状ZnO表面，成功制备了层状微观结构的金/氧化锌(Au/ZnO)复合材料。Au掺杂样品分别命名为Au/ZnO-SC、Au/ZnO-SB、Au/ZnO-SE和Au/ZnO-Hg灯。Au/ZnO- sc和Au/ZnO- sb在ZnO衬底上均匀分布，Au纳米粒子在Au/ZnO- se和Au/ZnO- hg灯样品中分布非常密集。纯ZnO只在紫外(UV)区有一个吸收峰，Au/ZnO样品在可见光(500 ~ 600 nm)区有额外的吸收峰，这是复合材料中Au纳米粒子表面等离子体共振(SPR)效应的特征。因此，与ZnO (3.202 eV)相比，它们的带隙能量降低，从而提高了可见光下的光催化效率。其中Au/ZnO-SC (Au含量为5 wt%)的比表面积最大(26.23 m2/g)，孔体积最大(0.263 cm3/g)，平均孔径为33.2 nm。结果表明，在Hg灯250的照射下，在30 min内完全降解酒黄石(TA)，反应速率为0.124 min−1，具有最高的催化效率。此外，纯ZnO和Au/ZnO纳米复合材料均具有较高的抑菌活性，其抑菌效果与Au与ZnO的质量比和样品浓度有关。这些结果表明，Au/ZnO材料在水环境处理中具有突出的应用潜力。版权所有©2023作者，BCREC集团出版。这是一篇基于CC BY-SA许可(https://creativecommons.org/licenses/by-sa/4.0)的开放获取文章。

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Bulletin of Chemical Reaction Engineering & Catalysis

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