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Small-size atom-driven distortion realizes high-entropy oxides with simultaneous chemical stability and activity enhancement enabling a practical cathode for solid oxide fuel cells

Wenjing Zhang, Wenjia Ma, Yuan Gao, Xu Han, Fangjun Jin, Ling Zhao, Kun Zheng, Yihan Ling, Peizhong Feng, Shaorong Wang, Zongping Shao

2025Applied Catalysis B: Environmental8 citationsDOI

Topics & Concepts

Density functional theoryCathodeCatalysisMaterials scienceOxideStructural stabilityPerovskite (structure)Unpaired electronChemical stabilityCrystal structureChemical physicsChemical engineeringOxygenLattice (music)Electronic structureSolid solutionChemical reactionNanotechnologyDopingChemical stateInorganic chemistryRedoxChemistryDistortion (music)Crystal (programming language)IonValence (chemistry)Density of statesPhysical chemistryPhase transitionSingle crystalAdvancements in Solid Oxide Fuel CellsHigh Entropy Alloys StudiesElectrocatalysts for Energy Conversion
Small-size atom-driven distortion realizes high-entropy oxides with simultaneous chemical stability and activity enhancement enabling a practical cathode for solid oxide fuel cells | Litcius