Energy storage technology is the ke

Energy storage technology is the key factor in harvesting kinetic energy. In the past decade there has been an ever-increasing demand for environmental friendly, high performance energy storage systems. Supercapacitors, also known as ultracapacitors, are the energy devices that store and release energy through nanoscopic charge separation at the electrochemical interface between a carbon electrode and a liquid electrolyte.1,2 Supercapacitors exhibit extremely high power density, reasonable energy density, longer cycle life, and minimum charge separation compared to those of conventional capacitors.3–7 These intriguing features have created a great interest towards the application of supercapacitors in the field of consumer electronics, heavy electric vehicles, and industrial power management.8 Batteries and fuel cells harvest the stored energy through chemical processes, whereas supercapacitors utilize electrostatic separation between electrolyte ions and high-surface area electrodes for harvesting energy. Due to their substantially high power capability and specific energy, supercapacitors can act as a bridge between batteries and conventional capacitors. However, an enormous amount of research still exists from the perspective of increasing the energy efficiency of supercapacitors, so that they may find their way into the market by replacing batteries. Advancement of supercapacitor technologies can benefit from the development of nanostructured electrode materials. Reasonably high surface area and optimum pore size of the electrode materials for an appropriate electrolyte solution play an important role in ensuring the excellent performance of a supercapacitor in terms of power density and energy storage capability.9 Various carbon-based materials have been considered as electrode materials for supercapacitors aimed at high specific capacitance (SC) coupled with high power and energy density.10–15 The underlying reason behind the improvement of performance of carbon-based electrode materials is due to the unique combination of chemical and physical properties,namely:2,9,10,16,17
- Reasonably high conductivity.
- Relatively high surface-area.
- Excellent corrosion resistance.
- High thermal stability.
- Controlled pore size distribution.
- Satisfactory compatibility in composite materials.
- Cost effectiveness.
Activated carbons are the most widely used electrode materials owing to their large surface area, low cost and easy processability.18,1 However, their applications are restricted by their poor energy storage capacity and inferior rate capability. Carbon-based materials such as, graphene and carbon nanotubes (CNTs) can be exploited as potential candidates for electrode materials due to their fascinating electrical and mechanical