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Light-to-Hydrogen Improvement Based on Three-Factored Au@CeO<sub>2</sub>/Gr Hierarchical Photocatalysts

Dung Van Dao, Hyuk Choi, Thuy T.D. Nguyen, Sang-Woo Ki, Gyu-Cheol Kim, Hoki Son, Jin‐Kyu Yang, Yeon‐Tae Yu, Hyun You Kim, In‐Hwan Lee

2022ACS Nano28 citationsDOI

Abstract

Recently, various attempts have been made for light-to-fuels conversion, often with limited performance. Herein we report active and lasting three-factored hierarchical photocatalysts consisting of plasmon Au, ceria semiconductor, and graphene conductor for hydrogen production. The Au@CeO 2 /Gr 2.0 entity (graphene outer shell thickness of 2.0 nm) under visible-light irradiation exhibits a colossal achievement (8.0 μmol mg cat –1 h –1 ), which is 2.2- and 14.3-fold higher than those of binary Au@CeO 2 and free-standing CeO 2 species, outperforming the currently available catalysts. Yet, it delivers a high maximum quantum yield efficiency of 38.4% at an incident wavelength of 560 nm. These improvements are unambiguously attributed to three indispensable effects: (1) the plasmon resonant energy is light-excited and transferred to produce hot electrons localizing near the surface of Au@CeO 2, where (2) the high-surface-area Gr conductive shell will capture them to direct hydrogen evolution reactions, and (3) the active graphene hybridized on the defect-rich surface of Au@CeO 2 favorably adsorbs hydrogen atoms, which all bring up thorough insight into the working of a ternary Au@CeO 2 /Gr catalyst system in terms of light-to-hydrogen conversion.

Topics & Concepts

Materials scienceGrapheneHydrogen productionHydrogenTernary operationPhotocatalysisQuantum yieldPlasmonCatalysisVisible spectrumWater splittingNanotechnologyPhotochemistryOptoelectronicsChemistryOpticsPhysicsBiochemistryFluorescenceComputer scienceOrganic chemistryProgramming languageAdvanced Photocatalysis TechniquesCopper-based nanomaterials and applicationsCatalytic Processes in Materials Science