Pt-Mediated Interface Engineering Boosts the Oxygen Reduction Reaction Performance of Ni Hydroxide-Supported Pd Nanoparticles

Keyphrases

• Oxygen Reduction Reaction 100%
• Reaction Performance 100%
• Interface Engineering 100%
• Supported Pd Nanoparticles 100%
• Ni Hydroxide 100%
• Pt Clusters 60%
• Nickel Hydroxide 40%
• Reversible Hydrogen Electrode 40%
• Pt Atom 40%
• In Situ 20%
• Atomic Scale 20%
• Potential Energy 20%
• Oxides 20%
• Electrochemical Analysis 20%
• X-ray Absorption Spectroscopy 20%
• Electrocatalyst 20%
• Mass Activity 20%
• Pt Catalyst 20%
• Fuel Cell 20%
• Novel Design 20%
• Nanocatalyst 20%
• Energy Conversion Device 20%
• Accelerated Durability Test 20%
• High Mass Activity 20%
• Character Analysis 20%
• Physical Characterization 20%
• Metal Hydroxide 20%
• Lattice Strain 20%
• Electrocatalytic Activity 20%
• NiOx 20%
• Utopia 20%
• Charge Localization 20%
• Pd Surface 20%
• Trimetallic Nanocatalyst 20%
• High Specific Activity 20%
• Yield Mode 20%
• Partial Fluorescence Yield 20%

Material Science

• Nanoparticle 100%
• Surface (Surface Science) 100%
• Oxide Compound 33%
• Electrochemical Reaction 33%
• X-Ray Absorption Spectroscopy 33%
• Electrocatalysts 33%