Litcius/Paper detail

Engineering Amorphous/Crystalline Rod-like Core–Shell Electrocatalysts for Overall Water Splitting

Linfeng Li, Huachuan Sun, Xuefei Xu, Muhammad Humayun, Xiang Ao, Muk Fung Yuen, Xinying Xue, Ying Wu, Yang Yang, Chundong Wang

2022ACS Applied Materials & Interfaces47 citationsDOI

Abstract

The design of bifunctional electrocatalysts for hydrogen and oxygen evolution reactions delivering excellent catalytic activity and stability is highly desirable, yet challenged. Herein, we report an amorphous RuO2-encapsulated crystalline Ni0.85Se nanorod structure (termed as a/c-RuO2/Ni0.85Se) for enhanced HER and OER activities. The as-prepared a/c-RuO2/Ni0.85Se nanorods not only demonstrate splendid HER activity (58 mV@10 mA cm–2 vs RHE), OER activity (233 mV@10 mA cm–2 vs RHE), and electrolyzer activity (1.488 V@10 mA cm–2 vs RHE for overall water splitting) but also exhibit long-term stability with negligible performance decay after 50 h continuous test for overall water splitting. In addition, the variation of the d-band center (from the perspective of bonding and antibonding states) is unveiled theoretically by density functional theory calculations upon amorphous RuO2 layers coupling to clarify the increased hydrogen species adsorption for HER activity enhancement. This work represents a new pathway for the fabrication of bifunctional electrocatalysts toward green hydrogen generation.

Topics & Concepts

Water splittingOxygen evolutionBifunctionalMaterials scienceAmorphous solidAntibonding molecular orbitalNanorodNanotechnologyChemical engineeringReversible hydrogen electrodeCatalysisCrystallographyElectrochemistryElectrodePhysical chemistryChemistryBiochemistryPhysicsEngineeringPhotocatalysisQuantum mechanicsAtomic orbitalElectronReference electrodeElectrocatalysts for Energy ConversionAdvanced battery technologies researchAdvanced Photocatalysis Techniques