Facile synthesis of mesoporous NiFe₂ O₄/CNTs nanocomposite cathode material for high performance asymmetric pseudocapacitors

Keyphrases

• Asymmetric Pseudocapacitors 100%
• Capacitance Retention 12%
• Capacitive Energy Storage 12%
• Carbon Nanotube Nanocomposites 12%
• Cathode Material 100%
• Charge-discharge Cycle 12%
• CNT Nanocomposites 100%
• Composite Materials 12%
• Conductive Network 12%
• Cubic Phase 12%
• Device Performance 12%
• Electrochemical Performance 12%
• Electrochemical Properties 12%
• Energy Storage Devices 12%
• Enhanced Electrochemical Performance 12%
• Excellent Performance 12%
• Facile Synthesis 100%
• Hexamethylenetetramine 12%
• High Performance 100%
• High Specific Surface Area 12%
• High Surface Area 12%
• Hydrothermal Approach 12%
• KOH Electrolyte 12%
• Maximum Energy Density 12%
• Mesopore Size Distribution 12%
• Mesoporous 100%
• Mesoporous Structure 12%
• Morphology Effect 12%
• Multi-walled Carbon Nanotubes (MWCNTs) 50%
• N-doped Graphene 12%
• Nanocomposite Cathode 100%
• Nanomaterials 12%
• Negative Electrode Material 12%
• NiFe2O4 100%
• One-step Hydrothermal Method 12%
• Physical-chemical Properties 12%
• Power Density 12%
• Relaxation Time Constant 12%
• Room Temperature 12%
• Specific Capacitance 12%
• Spinel 12%
• Superior Rate Capability 12%
• Synergistic Effect 12%
• Three-electrode System 12%

Material Science

• Capacitance 28%
• Carbon Nanotube 57%
• Cathode Material 100%
• Chemical Property 14%
• Composite Material 28%
• Composite Material 14%
• Density 14%
• Electrochemical Property 14%
• Energy Density 14%
• Graphene 14%
• Nanocomposite 100%
• Nanostructured Material 14%
• Physical Property 14%