选择性
光催化
等离子体子
化学
光化学
纳米技术
组合化学
化学工程
材料科学
光电子学
有机化学
催化作用
工程类
作者
Liteng Ren,Xiaonan Yang,Xin Sun,Yuling Wang,Huiquan Li,Yupeng Yuan
标识
DOI:10.1002/ange.202404660
摘要
Abstract Oxygen vacancies (O V ) in nonmetallic plasmonic photocatalysts can decrease the energy barrier for CO 2 reduction, boosting C1 intermediate production for potential C 2 formation. However, their susceptibility to oxidation weakens C1 intermediate adsorption. Herein we proposed a “photoelectron injection” strategy to safeguard O V in W 18 O 49 by creating a W 18 O 49 /ZIS (W/Z) plasmonic photocatalyst. Moreover, photoelectrons contribute to the local multi‐electron environment of W 18 O 49 , enhancing the intrinsic excitation of its hot electrons with extended lifetimes, as confirmed by in situ XPS and femtosecond transient absorption analysis. Density functional theory calculations revealed that W/Z with O V enhances CO 2 adsorption, activating *CO production, while reducing the energy barrier for *COH production (0.054 eV) and subsequent *CO−*COH coupling (0.574 eV). Successive hydrogenation revealed that the free energy for *CH 2 CH 2 hydrogenation (0.108 eV) was lower than that for *CH 2 CH 2 desorption for C 2 H 4 production (0.277 eV), favouring C 2 H 6 production. Consequently, W/Z achieves an efficient C 2 H 6 activity of 653.6 μmol g −1 h −1 under visible light, with an exceptionally high selectivity of 90.6 %. This work offers a new strategy for the rational design of plasmonic photocatalysts with high selectivity for C 2+ products.
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