用于改善电子-空穴分离及增强可见光驱动光催化性能的全固态Z型Bi-BiOCl/AgCl异质结微球

All-Solid Z-Scheme Bi-BiOCl/AgCl Heterojunction Microspheres for Improved Electron-Hole Separation and Enhanced Visible Light-Driven Photocatalytic Performance.

作者信息

Du Meng, Zhang Shiyu, Xing Zipeng, Li Zhenzi, Yin Junwei, Zou Jinlong, Zhu Qi, Zhou Wei

机构信息

Department of Environmental Science, School of Chemistry and Materials Science, Key Laboratory of Functional Inorganic Material Chemistry, Ministry of Education of the People's Republic of China , Heilongjiang University , Harbin 150080 , P. R. China.

Department of Epidemiology and Biostatistics , Harbin Medical University , Harbin 150086 , P. R. China.

出版信息

Langmuir. 2019 Jun 18;35(24):7887-7895. doi: 10.1021/acs.langmuir.9b00581. Epub 2019 Jun 5.

DOI:10.1021/acs.langmuir.9b00581

PMID:31185576

Abstract

All-solid Z-scheme Bi-BiOCl/AgCl heterojunction microspheres are successfully prepared via hydrothermal, NaBH reduction and chemical deposition strategy. They are tested by various characterization methods, and they show that metal Bi is present after reduction and AgCl nanoparticles are successfully compounded onto BiOCl. Bi plays the role of a bridge connecting the two semiconductors of BiOCl and AgCl. All-solid Z-scheme heterojunction structures are formed successfully. The narrow band gap of the Z-scheme Bi-BiOCl/AgCl heterojunction microspheres is about 2.17 eV, which can expand the optical response range. Moreover, the photocatalytic hydrogen production rate still reaches 198.2 μmol h g, extends the electron transport life, inhibits the recombination of electron hole pairs, and improves the photocatalytic activity.

摘要

通过水热法、硼氢化钠还原法和化学沉积策略成功制备了全固态Z型Bi-BiOCl/AgCl异质结微球。通过各种表征方法对其进行测试，结果表明还原后存在金属铋，且氯化银纳米颗粒成功复合到BiOCl上。铋起到连接BiOCl和AgCl两种半导体的桥梁作用。成功形成了全固态Z型异质结结构。Z型Bi-BiOCl/AgCl异质结微球的窄带隙约为2.17 eV，可扩大光响应范围。此外，光催化产氢速率仍达到198.2 μmol h g，延长了电子传输寿命，抑制了电子空穴对的复合，提高了光催化活性。

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用于改善电子-空穴分离及增强可见光驱动光催化性能的全固态Z型Bi-BiOCl/AgCl异质结微球

All-Solid Z-Scheme Bi-BiOCl/AgCl Heterojunction Microspheres for Improved Electron-Hole Separation and Enhanced Visible Light-Driven Photocatalytic Performance.

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