Rationalizing the Reactivity of Bimetallic Molecular Catalysts for CO₂ Hydrogenation

Keyphrases

• Bimetallic 100%
• CO2 Hydrogenation 100%
• Formate 100%
• Molecular Catalyst 100%
• Deprotonation 57%
• Hydride Transfer 57%
• Rate Limiting 28%
• Rational Design 14%
• Catalytic Processes 14%
• Thermodynamics 14%
• Catalytic System 14%
• Computational Study 14%
• Efficient Strategy 14%
• Heterobimetallic 14%
• Reaction Pathway 14%
• Steric Hindrance 14%
• Catalytic Activity 14%
• Reaction Rate 14%
• Reaction Mechanism 14%
• Tris 14%
• Binding Energy 14%
• Lewis Bases 14%
• Efficient Catalyst 14%
• Structure-activity Relationship 14%
• Amine Ligands 14%
• Transfer Process 14%
• Proton Shuttle 14%
• Activation Free Energy 14%
• Induction Period 14%
• Base Catalyst 14%
• Steady-state Period 14%
• Catalytic Turnover 14%
• Bimetallic Catalyst 14%
• Simple Strategy 14%
• Gallium(III) 14%
• Ni-based 14%
• Computational Calculations 14%
• Formate Production 14%
• Hydricity 14%

Chemistry

• Hydrogenation 100%
• Formate 100%
• Carbon Dioxide 100%
• Base 62%
• Deprotonation 50%
• Transfer Process 12%
• Tris 12%
• Gallium 12%
• Steric Hindrance 12%
• Free Energy of Activation 12%
• Metal Catalyst 12%
• Bimetallic Catalyst 12%
• Lewis Base 12%
• Binding Energy 12%
• Structure-Activity Relationship 12%
• Catalyst Activity 12%