Architecting in-plane bicrystals in BiOCl nanosheets for enhanced photocatalytic performance

光催化 同种类的 材料科学 热液循环 硫脲 降级(电信) 载流子 晶界 化学工程 可见光谱 纳米技术 异质结 电子迁移率 光电子学 吸收(声学) 纳米棒 催化作用
作者
Tingfang Xie,Shaodong Sun,Fangyuan Wang,Meiqi Ding,Jie Cui
出处
期刊:Nano materials science [Elsevier BV]
被引量:3
标识
DOI:10.1016/j.nanoms.2025.07.003
摘要

Interface engineering has emerged as an effective strategy for addressing challenges related to insufficient solar light harvesting and poor photocharge separation in photocatalysis. The distinctive in-plane homogeneous architecture offers the potential for significant enhancements in both photocharge separation and solar light absorption. Herein, a simple one-pot hydrothermal method was developed to construct in-plane homogeneous BiOCl bicrystals within BiOCl nanosheets (BOC-B). During this process, thiourea plays a pivotal role in introducing dislocations to form bicrystal structure. As expected, the synthesized BOC-B samples exhibited substantially higher photocatalytic degradation activity for TC and RhB compared to BOC. Notably, the mechanism underlying effective solar light absorption and charge carrier separation, driven by the homogeneous bicrystal structure, was elucidated through a series of experimental evidences. This work introduces a novel homogeneous bicrystal structure in BiOCl photocatalysts to optimize catalytic activity, providing a framework for developing new BiOCl-based photocatalysts. • In-plane BiOCl bicrystals were synthesized by a facile one-pot hydrothermal synthesis. • Defect engineering induced interfacial dislocations to form bicrystalline structures. • Dislocation-induced mid-gap states in BiOCl bicrystals can broaden visible light absorption. • In-plane bicrystalline architectures can enhance the electron mobility and charge separation. • The improved photocatalytic removal of TC and RhB was achieved.
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