Unravelling the Synergy between Oxygen Vacancies and Oxygen Substitution in BiO2−x for Efficient Molecular-Oxygen Activation

Yueshuang Mao, Dr. Pengfei Wang, Dr. Lina Li, Zongwei Chen, Prof. Haitao Wang, Prof. Yi Li, Prof. Sihui Zhan
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引用次数: 103

Abstract

Defects in nanomaterials often lead to properties that are absent in their pristine counterparts. To date, most studies have focused on the effect of single defects, while ignoring the synergy of multiple defects. In this study, a model of photocatalytic O2 activation was selected to unravel the role of dual defects by decorating bismuth oxide with surface O vacancies and bulk O substitution simultaneously. The introduction of dual defects led to a spatial and electronic synergistic process: i) O substitution induced a local electric field in the bulk of BiO2−x, which promoted bulk separation of electrons and holes immediately after their generation; ii) O vacancies efficiently lowered the conduction band, served as the capture center for electrons, and thus facilitated the adsorption and activation of O2. This effect was greatly promoted by the coexistence of bulk O substitution, and DFT calculations showed that only O substitution near an O vacancy could have this effect.

Abstract Image

揭示了BiO2 - x中氧空位和氧取代对高效分子氧活化的协同作用
纳米材料中的缺陷通常会导致其原始材料所没有的特性。迄今为止,大多数研究都集中在单个缺陷的影响上,而忽略了多个缺陷的协同作用。在这项研究中,我们选择了一个光催化O2活化模型,通过同时用表面O空位和体O取代来修饰氧化铋来揭示双缺陷的作用。双缺陷的引入导致了一个空间和电子协同过程:i) O取代在BiO2−x的体中诱导了一个局部电场,促进了电子和空穴在生成后的体分离;ii) O空位有效降低了导带,成为电子的捕获中心,有利于O2的吸附和活化。整体O取代的共存极大地促进了这种效应,DFT计算表明,只有O空位附近的O取代才会产生这种效应。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Angewandte Chemie
Angewandte Chemie 化学科学, 有机化学, 有机合成
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