High Entropy Spinel Oxide (AlCrCoNiFe₂)O as Highly Active Oxygen Evolution Reaction Catalysts

Keyphrases

• Highly Active 100%
• Oxygen Evolution Reaction 100%
• Active Oxygen 100%
• High-entropy Spinel Oxide 100%
• Oxygen Evolution Catalyst 100%
• High-entropy Ceramics 60%
• Charge Transfer Resistance 40%
• Strong Electronic Interaction 40%
• High-entropy Effect 40%
• Efficiency Improvement 20%
• Active Sites 20%
• Low Charge 20%
• AlCrN 20%
• Excellent Performance 20%
• Electrochemical Analysis 20%
• Enhanced Stability 20%
• Catalytic Activity 20%
• Material Structure 20%
• Electrocatalytic Performance 20%
• Electrocatalyst 20%
• High-performance Electrocatalysts 20%
• Reaction Performance 20%
• Tafel Slope 20%
• Catalytic Applications 20%
• Unique Properties 20%
• Spinel 20%
• Alkaline Condition 20%
• Electronic Configuration 20%
• Reaction Process 20%
• Valuable Insight 20%
• CoFe 20%
• Reaction Catalysis 20%
• Water Electrolysis 20%
• Lattice Distortion 20%
• Hydrogen Fuel 20%
• 3d Transition Metal 20%
• Clean Energy Technology 20%
• Al-Fe 20%
• Cost-effective Electrocatalysts 20%
• Configurational Entropy 20%
• Electrocatalytic Material 20%
• Sustainable Energy Consumption 20%
• Renewable Hydrogen 20%
• Sol-gel Auto-combustion Method 20%
• Monometallic Oxide 20%
• Multi-metal Oxide 20%

Material Science

• Oxide Compound 100%
• Oxygen Evolution 100%
• High Entropy Ceramics 50%
• Electrocatalysts 50%
• Aluminum 16%
• Transition Metal 16%
• Sol-Gel 16%
• Electrochemical Reaction 16%
• Catalysis 16%
• Catalyst Activity 16%
• Materials Structure 16%
• Hydrogen Fuels 16%