Joint tuning the morphology and oxygen vacancy of Cu₂O by ionic liquid enables high-efficient CO₂ reduction to C₂ products

Keyphrases

• High Efficiency 100%
• Oxygen Vacancy 100%
• Copper(II) Oxide 100%
• Ionic Liquid 100%
• CO2 Reduction Reaction (CO2RR) 100%
• C2+ Products 100%
• Cu2O Nanoparticles 66%
• Surfactant 33%
• Bifunctional 33%
• Density Functional Calculations 33%
• Excellent Catalytic Performance 33%
• Metal Oxide 33%
• In Situ 33%
• Rough Surface 33%
• Chloride 33%
• Composite Catalyst 33%
• Abundant Oxygen Vacancies 33%
• Cu + 33%
• Current Density 33%
• Adsorption 33%
• Graphite Nanosheets 33%
• Electrochemical CO2 Reduction 33%
• Multi-carbon Products 33%
• Surface-enhanced Raman Spectroscopy 33%
• Structure-directing Agent 33%
• High Faradaic Efficiency 33%
• C-C Coupling Reaction 33%
• Carbon Emissions 33%
• Efficient Electrocatalyst 33%
• Flow Cell 33%
• 1-octyl-3-methylimidazolium 33%
• Renewable Electricity 33%
• Surface Oxygen Vacancy 33%
• Controllable Morphology 33%
• Electrochemical Applications 33%

Material Science

• Carbon Dioxide 100%
• Oxygen Vacancy 100%
• Ionic Liquid 100%
• Nanoparticle 66%
• Density 66%
• Rough Surface 33%
• Surface Active Agent 33%
• Surface-Enhanced Raman Spectroscopy 33%
• Metal Oxide 33%
• Nanosheet 33%
• Structure-Directing Agent 33%
• Electrocatalysts 33%

Chemical Engineering

• Nanoparticle 100%
• Carbon Dioxide Reduction 100%
• Nanosheet 50%
• Carbon Dioxide 50%
• Surfactant 50%
• Electrochemical CO2 reduction 50%