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Large‐Area Printing of Ferroelectric Surface and Super‐Domain for Solar Water Splitting

Yu Tian, Aiji Wang, Yaqing Wei, Minghui Pei, Rongrong Cao, Zhenao Gu, Qi Yuan, Yiwen Hu, Jing Wang, Kunhui Liu, Dashan Shang, Jiebin Niu, Xiaoqiang An, Run Long, Jinxing Zhang

2022Advanced Functional Materials38 citationsDOI

Abstract

Abstract Surface electronic structures of the photoelectrodes determine the activity and efficiency of the photoelectrochemical water splitting, but the control of surface structures and interfacial chemical reactions remain challenging. Here, ferroelectric BiFeO 3 is used as a model system to demonstrate a controllable water splitting reaction by large‐area constructing the hydroxyls‐bonded surface. The up‐shift of band edge positions at this ferroelectric surface enables and enhances the holes and electrons transfer through the hydroxyl‐active sites, leading to enhanced oxygen or hydrogen evolutions, respectively. Furthermore, the printing of ferroelectric super‐domain with microscale checkboard up/down electric fields enhances the photogenerated carriers separation and gives rise to an order of magnitude increase of the photocurrent. This large‐area printable ferroelectric surface and super‐domain offer an alternative platform for controllable and efficient photocatalysis.

Topics & Concepts

FerroelectricityMaterials sciencePhotocurrentWater splittingMicroscale chemistryPhotocatalysisNanotechnologyOptoelectronicsEnhanced Data Rates for GSM EvolutionElectric fieldChemical physicsChemistryComputer scienceQuantum mechanicsMathematics educationMathematicsTelecommunicationsPhysicsCatalysisDielectricBiochemistryAdvanced Photocatalysis TechniquesMultiferroics and related materialsPerovskite Materials and Applications
Large‐Area Printing of Ferroelectric Surface and Super‐Domain for Solar Water Splitting | Litcius