Keyphrases
Supercapacitor Application
100%
Co-doped Graphene
100%
Aqueous Electrolyte
100%
Hierarchical Porous
100%
3D Cross-linked
100%
Heteroatom Doping
100%
Cross-linked Graphene
100%
Pentafluoropyridine
100%
Diffusion Coefficient
50%
Performance Improvement
50%
High Specific Surface Area
50%
Electrochemical Reactions
50%
Reduced Graphene Oxide
50%
Synthetic Approaches
50%
High Power
50%
Electrochemical Properties
50%
Doped Graphene Oxide
50%
Anode Material
50%
Energy Value
50%
Electrochemical Impedance Spectroscopy
50%
Power Energy
50%
Calculation Results
50%
Atomic Level
50%
Capacitance Retention
50%
Specific Capacitance
50%
Electrolyte
50%
Eco-friendly
50%
Density Functional Calculations
50%
Facile Synthesis
50%
Well-balancing
50%
Cathode Material
50%
High Energy Density
50%
Level Energies
50%
Superior Rate Capability
50%
Electrochemical Analysis
50%
Kinetic Processes
50%
Relaxation Time Constant
50%
Energy Supply
50%
Graphene-based Supercapacitor
50%
Freeze-drying
50%
Three-electrode
50%
Heteroatom
50%
Voltammetry
50%
Specific Power
50%
Fast Kinetics
50%
Specific Energy
50%
Energy Storage Performance
50%
Galvanostatic Charging-discharging
50%
Short Relaxation Time
50%
Nitrogen Phosphorus
50%
Ion Transport Phenomena
50%
Coin Cell Supercapacitor
50%
Hierarchical Pores
50%
Atomic Replacement
50%
Phytic Acid
50%
Supercapacitor Device
50%
Material Science
Graphene
100%
Supercapacitors
100%
Capacitance
50%
Density
25%
Diffusivity
25%
Electrochemical Reaction
25%
Reduced Graphene Oxide
25%
Dielectric Spectroscopy
25%
Electrochemical Property
25%
Graphene Oxide
25%
Anode Material
25%
Voltammetry
25%
Energy Density
25%
Pore Structure
25%
Cathode Material
25%
Transport Phenomena
25%
Chemical Engineering
Graphene
100%
Hierarchical Porous
100%
Diffusion
20%
Heteroatom Doping
20%