Litcius/Paper detail

MXenes enhance electrocatalytic water electrolysis of NiFe layered double hydroxides through bifunctional heterostructuring

Nannan Li, Xiaotong Han, Ho Seok Park, Jin Yong Lee

2025Physical Chemistry Chemical Physics8 citationsDOIOpen Access PDF

Abstract

Transition metal-based layered double hydroxides (TM-LDHs) are among the most promising catalytic materials for the electrochemical reactions involved in energy conversion and storage technology. We systematically investigate NiFe-LDH-based electrocatalysts toward application in water electrolysis. We start with the highly accurate advanced density functional theory description of NiFe-LDH's fundamental properties, and demonstrate that coupling a spin-polarized p-band or d-band center model with the Gibbs free energy calculations explains NiFe-LDH's oxygen evolution reaction (OER) mechanism. By involving the related transient states, a reversible oxygen vacancy assisted reaction mechanism has been directly observed and motivated by the high spin transition metal impurity which is further confirmed by the time-consuming hybrid functional method. To further facilitate the electrocatalytic activity of NiFe-LDH, we study NiFe-LDH/MXene heterostructures where the essential semiconductor-to-metallic transition takes place by the additional Ti-3d orbitals and the interfacial non-covalent interaction between the two catalysts. On the basis of calculated results, we propose a link between microscopic properties and macroscopic electrocatalytic kinetics of heterogenous electrocatalysts. Accurately describing the electronic and magnetic structures of electrocatalysts leads us to a step-by-step process for tailoring desired electrocatalytic properties, especially for the high spin state contained TM-LDHs. A descriptor based on combination of the calculated d-band center of transition metal and p-band center of oxygen is the key to predicting electrochemical activity and stability of oxide electrocatalysts. From our results, we establish a design strategy for NiFe-LDH-based bifunctional electrocatalyst fabrication.

Topics & Concepts

Layered double hydroxidesOxygen evolutionBifunctionalMXenesMaterials scienceTransition metalElectrochemistryElectrolysisWater splittingOxideDensity functional theoryCatalysisGibbs free energyElectrolysis of waterGrapheneInorganic chemistryChemistryChemical physicsNanotechnologyPhysical chemistryComputational chemistryHydroxideElectrodeElectrolyteThermodynamicsPhotocatalysisPhysicsMetallurgyBiochemistryMXene and MAX Phase MaterialsAdvanced Photocatalysis TechniquesNanomaterials for catalytic reactions