Improving SERS Sensing Efficiency and Catalytic Reduction Activity in Multifunctional Ternary Ag-TiO2-GO Nanostructures: Roles of Electron Transfer Process on Performance Enhancement

IF 2.8 4区 工程技术 Q2 CHEMISTRY, APPLIED
Mai Quan Doan, Nguyen Ha Anh, Hoang Van Tuan, N. C. Tu, N. H. Lam, Nguyen Tien Khi, Vu Ngoc Phan, P. D. Thang, Anh-Tuan Le
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引用次数: 3

Abstract

Multifunctional nanocomposites have received great attention for years; electron transfer (ET) is considered as an explanatory mechanism for enhancement of performance of these nanostructures. The existence of this ET process has been proved in many studies using either experimental or computational approaches. In this study, a ternary nanocomposite system of Ag/TiO2/GO was prepared to evaluate the performance enhancement in two experimental models: a physical model (i.e., surface-enhanced Raman scattering (SERS) sensor) and a chemical one (i.e., catalytic reduction reaction). The metal/semiconductor heterojunction between Ag and TiO2, as well as Ti-O-C bonds, has allowed plasmonic hot electrons to be transferred in the internal structure of the material. An investigation on the role of Ag content on the SERS sensing and catalytic reduction efficiency of Ag/TiO2/GO was performed in both models. Interestingly, they all resulted in the same optimal Ag content of 50 wt%. It was then further discussed to provide a convincing evidence for the plasmon-induced electron transfer phenomena in the Ag/TiO2/GO nanostructure. These findings also suggest a pathway to design and develop high-performance, cost-effective, facile-preparation, and eco-friendly multifunctional nanostructures for detecting and removing contaminants in environment.
提高多功能三元Ag-TiO2-GO纳米结构SERS传感效率和催化还原活性:电子转移过程对性能增强的作用
多年来,多功能纳米复合材料受到了极大的关注;电子转移(ET)被认为是增强这些纳米结构性能的解释机制。这种ET过程的存在已经在许多使用实验或计算方法的研究中得到了证明。在本研究中,制备了Ag/TiO2/GO三元纳米复合材料体系,以评估两个实验模型的性能增强:物理模型(即表面增强拉曼散射(SERS)传感器)和化学模型(即催化还原反应)。Ag和TiO2之间的金属/半导体异质结以及Ti-O-C键使等离子体热电子能够在材料的内部结构中转移。在这两个模型中,研究了Ag含量对Ag/TiO2/GO的SERS传感和催化还原效率的影响。有趣的是,它们都产生了相同的最佳Ag含量,即50 重量%。然后进一步讨论,为Ag/TiO2/GO纳米结构中等离子体诱导的电子转移现象提供了令人信服的证据。这些发现还为设计和开发高性能、低成本、易于制备和环保的多功能纳米结构提供了一条途径,用于检测和去除环境中的污染物。
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来源期刊
Adsorption Science & Technology
Adsorption Science & Technology 工程技术-工程:化工
CiteScore
5.00
自引率
10.30%
发文量
181
审稿时长
4.5 months
期刊介绍: Adsorption Science & Technology is a peer-reviewed, open access journal devoted to studies of adsorption and desorption phenomena, which publishes original research papers and critical review articles, with occasional special issues relating to particular topics and symposia.
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