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A Stacked Plasmonic Metamaterial with Strong Localized Electric Field Enables Highly Efficient Broadband Light‐Driven CO<sub>2</sub> Hydrogenation

Tianyi Shao, Xiaonong Wang, Hanxiao Dong, Shengkun Liu, Delong Duan, Yaping Li, Pin Song, Huijun Jiang, Zhonghuai Hou, Chao Gao, Yujie Xiong

2022Advanced Materials84 citationsDOI

Abstract

Abstract Light utilization largely governs the performance of CO 2 photoconversion, whereas most of the materials that are implemented in such an application are restricted in a narrow spectral absorption range. Plasmonic metamaterials with a designable regular pattern and facile tunability are excellent candidates for maximizing light absorption to generate substantial hot electrons and thermal energy. Herein, a concept of coupling a Au‐based stacked plasmonic metamaterial with single Cu atoms in alloy, as light absorber and catalytic sites, respectively, is reported for gas‐phase light‐driven catalytic CO 2 hydrogenation. The metamaterial structure works in a broad spectral range (370–1040 nm) to generate high surface temperature for photothermal catalysis, and also induces strong localized electric field in favor of transfer of hot electrons and reduced energy barrier in CO 2 hydrogenation. This work unravels the significant role of a strong localized electric field in photothermal catalysis and demonstrates a scalable fabrication approach to light‐driven catalysts based on plasmonic metamaterials.

Topics & Concepts

Materials sciencePlasmonMetamaterialPhotothermal therapyElectric fieldOptoelectronicsAbsorption (acoustics)Metamaterial absorberNanotechnologyQuantum mechanicsPhysicsComposite materialTunable metamaterialsSolar-Powered Water Purification MethodsThermal Radiation and Cooling TechnologiesZnO doping and properties