A highly mismatched NiO₂-to-Pd hetero-structure as an efficient nanocatalyst for the hydrogen evolution reaction

Keyphrases

• Heterostructure 100%
• Carbon Nanotubes 100%
• Hydrogen Evolution Reaction 100%
• Nanocatalyst 100%
• NiO2 100%
• Ni-Pd 80%
• Tafel Slope 60%
• DEC1 40%
• Active Sites 20%
• Highly Active 20%
• Sulfuric Acid 20%
• Current Density 20%
• Epitaxial Structure 20%
• Chemical Reduction 20%
• Reaction Performance 20%
• Bimetallic 20%
• Bimetallic Nanocatalyst 20%
• Slope Value 20%
• Ni Oxide 20%
• Power Generation Device 20%
• Electronegativity Difference 20%
• Wet Chemical Reduction 20%
• Metallic Pd 20%
• Excellent Catalytic Performance 20%
• Pd-based 20%
• Competitive Behavior 20%
• Alternative Power Generation 20%
• Pt Nanocatalyst 20%
• Acidic Medium 20%
• Lattice Mismatch 20%
• Unique Structure 20%
• Low Overpotential 20%
• Reaction Kinetics 20%
• Efficient Generation 20%
• Hydrogen Generation 20%
• Catalyst Surface 20%
• Pd Nanocrystals 20%
• Contextual Search 20%
• Key Enabling Technologies 20%

Material Science

• Heterojunction 100%
• Hydrogen Evolution 100%
• Carbon Nanotube 100%
• Oxide Compound 20%
• Density 20%
• Catalyst Activity 20%
• Lattice Mismatch 20%
• Surface (Surface Science) 20%

Chemistry

• Hydrogen 100%
• Carbon Nanotube 83%
• Electronegativity 16%
• Current Density 16%
• formation 16%
• stability 16%
• Nanocrystalline Material 16%
• Catalyst Activity 16%