Controlled multimodal hierarchically porous electrode self-assembly of electrochemically exfoliated graphene for fully solid-state flexible supercapacitor

Keyphrases

• Micropore 100%
• Electrochemically Exfoliated Graphene 100%
• Graphene Electrodes 100%
• Hierarchically Porous 100%
• Flexible Solid-state Supercapacitor 100%
• Porous Electrode 100%
• Self-assembly 100%
• Micro-meso-macro 100%
• Mesopore 100%
• Macropores 66%
• 3D Graphene 66%
• 3D Architecture 66%
• Supercapacitor 66%
• High Performance 33%
• High Efficiency 33%
• Synthesis Methods 33%
• Graphene-based Materials 33%
• Mechanical Flexibility 33%
• Wearable Devices 33%
• Energy Density 33%
• Specific Surface Area 33%
• Sulfuric Acid 33%
• Pore Structure 33%
• Superior Durability 33%
• Specific Capacitance 33%
• Binder 33%
• Electrolyte 33%
• Environmentally Friendly 33%
• Free Energy 33%
• Graphene Structure 33%
• Capacitance Retention 33%
• Porous Graphene 33%
• Accessible Surface Area 33%
• Gel Polymer Electrolyte 33%
• Solid-state Electrolyte 33%
• Flexible All-solid-state 33%
• Worthiness 33%
• Costing Methods 33%
• Ion Diffusion Kinetics 33%
• Energy Storage Devices 33%
• Facile Method 33%
• Carbon Conductive Additives 33%
• Power Delivery 33%
• Delivery Rate 33%
• Electric Double Layer Capacitor 33%
• Electron Transport 33%
• One-step Method 33%
• Micron-sized 33%
• Microporous Network 33%
• Power Energy 33%
• Binder-free 33%
• Ion-buffering Reservoirs 33%
• Folding Angle 33%
• Macro-mesoporous 33%
• Concentration-dependent 33%
• Additive-free 33%

Material Science

• Graphene 100%
• Self Assembly 100%
• Supercapacitors 100%
• Capacitance 28%
• Capacitor 14%
• Energy Density 14%
• Electron Transfer 14%
• Pore Structure 14%
• Solid Electrolyte 14%
• Wearable Sensor 14%

Chemical Engineering

• Graphene 100%
• Hierarchically Porous 100%
• Free Energy 14%