光催化
试剂
催化作用
光化学
活动中心
化学
氨
兴奋剂
原位
固氮
电子转移
基质(水族馆)
氮气
材料科学
化学工程
有机化学
海洋学
地质学
工程类
光电子学
作者
Zhengfeng Shen,Feifei Li,Jiangrui Lu,Zhidan Wang,Rui Li,Xiaochao Zhang,Changming Zhang,Yawen Wang,Yunfang Wang,Zhiping Lv,Jianxin Liu,Caimei Fan
标识
DOI:10.1016/j.jcis.2020.09.111
摘要
Photocatalytic nitrogen fixation has been considered to be a safe, green, eco-friendly, and sustainable technology. However, photoinduced activation of inert dinitrogen is an important factor hindering the development of this technology. Herein, in-situ Fe3+ doped flower-like BiOCl with highly active sites exposure was prepared by a solvent thermal method, which has excellent performance of N2 photofixation. Compared with virgin BiOCl with no nitrogen fixation activity, Fe-BiOCl reached 30 μmol·L−1·h−1 ammonia evolution rate under simulated sunlight without any sacrificial reagent. Characterization results demonstrated that the enhancement of N2 photofixation capacity was mainly attributed to the in-situ doped Fe3+ in BiOCl, the doped Fe3+ not only acts as a reaction center for N2 activation also as an “electron transfer bridge” trapping and migrating electrons from BiOCl to N2 molecules. Furthermore, the transformation of crystal facets from virgin BiOCl (0 0 1) to Fe-BiOCl (1 1 0) and (1 0 2) is more conducive for the exposure and accessibility of iron reactive sites. This work developed a potential strategy by in-situ introducing Fe3+ active sites in BiOCl semiconductor substrate, which establishes a good basis for the application of semiconductor catalysts in nitrogen fixation.
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