Cu<sub>2</sub>O/CeO<sub>2</sub> Photo‐electrochemical Water Splitting: A Nanocomposite with an Efficient Interfacial Transmission Path under the Co‐action of a p–n Heterojunction and Micro‐mesocrystals
Gangrong Tang, Yu Wu, Jinghong Zhao, Huijuan Zhang, Miao Zhou, Yu Wang
Abstract
Abstract Cu 2 O is an ideal p‐type material for photo‐electrochemical (PEC) hydrogen evolution, although serious electron–hole recombination and photocorrosion restrict its further improvement for PEC activity. In this work, CeO 2 nanoparticles (NPs) self‐assemble on the surface of Cu 2 O octahedra, thus successfully forming a Cu 2 O/CeO 2 structure in which p–n heterojunctions and micro‐mesocrystals (m‐MCs) work together. The optimum Cu 2 O/CeO 2 composite, without the use of any cocatalyst, exhibits a fivefold higher photocurrent density (4.63 mA cm −2 at 0 V vs. the reversible hydrogen electrode) than that of Cu 2 O octahedra, which is better than most Cu 2 O‐based photocathodes without cocatalyst and even comparable with advanced Cu 2 O‐based photocathodes. The hydrogen production of the optimal Cu 2 O/CeO 2 (Faradaic efficiency of ∼100 %) is 17.5 times higher than that of pure Cu 2 O octahedra, and the photocurrent shows almost no decay under the 12 h stability test. The delicately designed Cu 2 O/CeO 2 structure in this work provides reference and inspiration for the design of cathodes materials.