Interface engineering in inorganic hybrid structures towards improved photocatalysis (Conference Presentation)

Optics + Photonics for Sustainable Energy Pub Date : 2016-09-01 DOI:10.1117/12.2237257

Y. Xiong

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Abstract

Designing new photocatalytic materials for improving photoconversion efficiency is a promising route to alleviate the steadily worsening environmental issues and energy crisis. Despite the invention of a large number of catalytic materials with well-defined structures, their overall efficiency in photocatalysis is still quite limited as the three key steps  light harvesting, charge generation and separation, and charge transfer to surface for redox reactions  have not been substantially improved. To improve each step in the complex process, there is a major trend to develop materials based on inorganic hybrid structures. In this case, interface engineering holds the promise for boosting the overall efficiency, given the key roles of interface structures in charge and energy transfer. In this talk, I will demonstrate several different approaches to designing inorganic hybrid structures with improved photocatalytic performance via interface engineering. The typical demonstrations include semiconductor-plasmonics systems for broad-spectrum light harvesting, metal-semiconductor interfaces for improved charge separation, semiconductor-MOF (metal-organic framework) configurations for activated surface reactions. It is anticipated that this series of works open a new window to rationally designing inorganic hybrid materials for photo-induced applications. References: (1) Bai, S.; Yang, L.; Wang, C.; Lin, Y.; Lu, J.; Jiang, J. and Xiong, Y.*, Angew. Chem. Int. Ed. 54, 14810-14814 (2015). (2) Bai, S.; Jiang, J.; Zhang, Q. and Xiong, Y.*, Chem. Soc. Rev. 44, 2893-2939 (2015). (3) Bai, S.; Li, X.; Kong, Q.; Long, R.; Wang, C.; Jiang, J. and Xiong, Y.*, Adv. Mater. 27, 3444-3452 (2015). (4) Bai, S.; Ge, J.; Wang, L.; Gong, M.; Deng, M.; Kong, Q.; Song, L.; Jiang, J.;* Zhang, Q.;* Luo, Y.; Xie, Y. and Xiong, Y.*, Adv. Mater. 26, 5689-5695 (2014). (5) Li, R.; Hu, J.; Deng, M.; Wang, H.; Wang, X.; Hu, Y.; Jiang, H. L.; Jiang, J.;* Zhang, Q.;* Xie, Y. and Xiong, Y.*, Adv. Mater. 26, 4783-4788 (2014).

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面向改进光催化的无机杂化结构界面工程(会议报告)

设计新型光催化材料以提高光转化效率是缓解日益恶化的环境问题和能源危机的一条有希望的途径。尽管发明了大量具有明确结构的催化材料，但它们在光催化中的整体效率仍然非常有限，因为三个关键步骤(光收集、电荷产生和分离以及用于氧化还原反应的电荷转移到表面)没有得到实质性的改善。为了改进复杂过程中的每一步，发展基于无机杂化结构的材料是一个主要趋势。在这种情况下，考虑到界面结构在电荷和能量传递中的关键作用，界面工程有望提高整体效率。在这次演讲中，我将展示几种不同的方法，通过界面工程设计具有改进光催化性能的无机杂化结构。典型的演示包括用于广谱光捕获的半导体等离子体系统，用于改进电荷分离的金属-半导体界面，用于激活表面反应的半导体- mof(金属-有机框架)结构。期待这一系列的工作为合理设计光致无机杂化材料打开一扇新的窗口。参考文献:(1)Bai, S.;杨,l;王,c;林,y;陆,j .;蒋杰，熊艳*，杨建平，杨建平。化学。Int。编辑54,14810-14814(2015)。(2)白，s;江,j .;张琪，熊艳*，化学。Soc。Rev. 44, 2893-2939(2015)。(3)白，s;李,x;问:香港;长,r;王,c;蒋军，熊艳*，高分子学报，27,3444-3452(2015)。(4)白，s;通用电气,j .;王,l;锣,m;邓,m;问:香港;歌,l;*张强;*罗勇;谢艳，熊艳*，高分子学报，26,5689-5695(2014)。(5)李仁;胡,j .;邓,m;王,h;王,x;胡,y;蒋海林;*张强，*谢艳，*熊艳*，生物工程学报，26，(2014):483 - 488。

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Optics + Photonics for Sustainable Energy

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