In Situ Stability Studies of Platinum Nanoparticles Supported on Ruthenium-Titanium Mixed Oxide (RTO) for Fuel Cell Cathodes

Keyphrases

• Rutile 100%
• Stability Study 100%
• Ruthenium 100%
• Platinum Nanoparticles (PtNPs) 100%
• Fuel Cell Cathode 100%
• Mixed Oxides 100%
• In Situ Stability 100%
• Fuel Cell 66%
• In Situ 33%
• Oxides 33%
• Degradation Pathway 33%
• Catalytic Activity 33%
• Inductively Coupled Plasma Mass Spectrometry 33%
• Pt Nanoparticles 33%
• Structural Stability 33%
• Operating Conditions 33%
• In Situ Techniques 33%
• Cell Measurement 33%
• Atomic Composition 33%
• Catalytic Rate 33%
• Electrolyzers 33%
• Electrocatalyst 33%
• Potential Cycling 33%
• Metal Particles 33%
• Particle Growth 33%
• High-temperature X-ray Diffraction (HT-XRD) 33%
• Metal Support 33%
• Strong Metal-support Interaction 33%
• Metal-air Battery 33%
• Thin Oxides 33%
• Catalyst Degradation 33%
• Accelerated Stress Test 33%
• Supported Pt Nanoparticles 33%
• Catalytic Oxygen Reduction Reaction Activity 33%
• Oxide Support 33%
• Pt Surface 33%
• Electrocatalytic Oxygen Reduction Reaction 33%
• Pt Agglomeration 33%
• Gradual Growth 33%
• Mixed Oxide Support 33%
• Surface Poisoning 33%
• Scanning Flow Cell 33%

Material Science

• Nanoparticle 100%
• Platinum 100%
• Titanium 100%
• Oxide Compound 100%
• Ruthenium 100%
• Cathode 100%
• Oxygen Reduction Reaction 33%
• Stress Analysis 16%
• X-Ray Diffraction 16%
• Inductively Coupled Plasma Mass Spectrometry 16%
• Catalyst Activity 16%
• Surface (Surface Science) 16%
• Electrocatalysts 16%
• Particle Growth 16%

Chemical Engineering

• Nanoparticle 100%
• Inductively Coupled Plasma Mass Spectrometry 25%
• Strong Metal-Support Interaction 25%