Engineering Particle Size for Multivalent Ion Intercalation: Implications for Ion Battery Systems

Keyphrases

• Particle Size 100%
• Battery System 100%
• Li-ion Battery 100%
• Cathode Particles 100%
• Multivalent Ion Intercalation 100%
• Ion Insertion 66%
• Phase Transformation 50%
• Size Effect 33%
• Particle Size Effect 33%
• Transformation Pathways 33%
• Mg Ions 33%
• Multivalent Ions 33%
• Zn(II) Ions 33%
• Side Reactions 33%
• Mechanical Stability 16%
• Surface Chemistry 16%
• Discharge Capacity 16%
• Phase Transition 16%
• Scanning Transmission Electron Microscopy 16%
• Micron-sized 16%
• Solid Solution 16%
• Electron Beam Scanning 16%
• Spinel 16%
• Composition Variation 16%
• Ion Distribution 16%
• Reaction Mechanism 16%
• Monovalent Ions 16%
• Insertion Kinetics 16%
• Mechanistic Understanding 16%
• Transition Pathways 16%
• Reaction Sites 16%
• Performance Capacity 16%
• Cathode Material 16%
• Interpenetrating Network 16%
• Micron Particles 16%
• Transferrable 16%
• Cycling Performance 16%
• Kinetic Stability 16%
• Solution Types 16%
• Fast Charging 16%
• Exposed Facets 16%
• Transformation Reactions 16%
• High-resolution Imaging Methods 16%
• Aqueous Zn-ion Batteries 16%
• Mn Dissolution 16%
• Metal-ion Batteries 16%
• High-performance Electrode Material 16%
• Insertion Systems 16%
• Multiphase Transition 16%
• Enhanced Cycling Performance 16%
• Insertion Materials 16%
• Electrochemical Reaction Mechanism 16%
• Scanning Electron Diffraction 16%
• Monitoring Structural Changes 16%
• Mesoscale Assembly 16%

Material Science

• Cathode 100%
• Battery (Electrochemical Energy Engineering) 100%
• Magnesium Ion 33%
• Zinc Ion 33%
• Electron Diffraction 16%
• Amorphous Material 16%
• Mechanical Stability 16%
• Scanning Transmission Electron Microscopy 16%
• Electrochemical Reaction 16%
• Solid Solution 16%
• Cathode Material 16%
• Aqueous Zinc-Ion Battery 16%