Compositing redox-rich Co-Co@Ni-Fe PBA nanocubes into cauliflower-like conducting polypyrrole as an electrode material in supercapacitors

Keyphrases

• Electrode Materials 100%
• Redox 100%
• Supercapacitor 100%
• FeCo 100%
• Prussian Blue Analogues 100%
• Nanocubes 100%
• Cauliflower-like 100%
• Conductive Polypyrrole 100%
• Polypyrrole 36%
• Core-shell 18%
• Redox Additive 18%
• Morphological Changes 9%
• Power Density 9%
• Electron Transfer 9%
• Capacitance 9%
• Energy Density 9%
• Reaction Rate 9%
• Redox Couple 9%
• Fe(II) 9%
• Activated Carbon Electrode 9%
• Electrochemical Characterization 9%
• Electrochemical Analysis 9%
• Electrochemically Active Surface Area 9%
• Metal-organic Frameworks (MOFs) 9%
• Novel Polymers 9%
• Asymmetric Supercapacitor 9%
• Conducting Polymer 9%
• Tri-metallic 9%
• Material Level 9%
• Carbonized Polypyrrole 9%
• Charge Storage Performance 9%
• Common Metals 9%
• Electroactive Sites 9%
• Strong Electronic Coupling 9%
• Redox Materials 9%
• Maximum Energy Density 9%
• Capacity Retention 9%
• Faradaic 9%
• Charge Storage Ability 9%
• Voltage Window 9%
• Low Conductivity 9%
• Optimization Strategy 9%
• Electrolyte Diffusion 9%
• Current Contribution 9%
• NiFe 9%
• Level Optimization 9%
• Diffusion Zone 9%
• Reversible Redox Reaction 9%

Material Science

• Supercapacitors 100%
• Polypyrrole 100%
• Composite Material 50%
• Energy Density 33%
• Density 16%
• Electron Transfer 16%
• Electrochemical Reaction 16%
• Capacitance 16%
• Redox Process 16%
• Metal-Organic Framework 16%
• Asymmetric Supercapacitor 16%
• Superlattice 16%
• Conducting Polymer 16%