Hyderabad, NFAPost : In what could be a game-changer for corn-producing states like Andhra Pradesh, Telangana and Uttar Pradesh, researchers of the Indian Institute of Technology, Hyderabad have developed a simple and cost-effective method to derive ‘activated carbon electrode’ material from cornhusk for high-voltage supercapacitors.
Their electrode showed better electrochemical performance (High energy density and high-power density) when compared with conventional supercapacitors.
This development is important for India, especially for States such as Uttar Pradesh and the combined Andhra Pradesh-Telangana States, which are the first and second-largest producers of corn in the country respectively.
They produce a large amount of cornhusk waste, much of which waste is currently burnt as its potential to be converted to valuable electrode material is not harnessed owing to lack of awareness, expertise and technology.
Earning for corn-farmer
This Research by IIT Hyderabad on affordable and efficient methods can enable this conversion, which would trigger the cascade of additional earning opportunity for the corn-farmer and provision of a sustainable energy source.
The research was led by Dr Atul Suresh Deshpande, Associate Professor, Department of Materials Science and Metallurgical Engineering, IIT Hyderabad, in collaboration with Dr T. N. Rao, Associate Director, International Advanced Research Centre for Powder Metallurgy and New Materials (ARCI), Hyderabad, along with their Research students, M. Usha Rani, and K. Nanaji (Project Scientist).
Their Research paper detailing the synthesis procedure and the electrochemical performance of the material produced has been recently published in the reputed peer-reviewed Journal of Power Sources.
Global market value
In the global sector, rapid advancements in adopting new technology and fast-evolving green energy systems are trending in the supercapacitor’s market. It is projected to share USD 720 million by 2025 market value, which is expected to grow at a CAGR of 12 per cent from 2020 to 2025.
Carbon-based electrodes are playing a crucial role in the development of energy storage devices. Carbon-based electrodes are typically derived from expensive, high purity precursors such as polymers, organic precursors, high purity gases using various methods. The production of carbon electrodes from biomass is a simpler straightforward process.
In collaboration with ARCI (Hyderabad), the IIT Hyderabad team has developed activated carbon electrode using simple materials – Corn husk and KOH.
Explaining his research, Dr Atul Suresh Deshpande, Associate Professor, Department of Materials Science and Metallurgical Engineering, IIT Hyderabad, said, “Activated carbon electrode material with porous sheet-like morphology has been prepared using corn husk through carbonization followed by KOH activation.
“Due to the low-cost precursors and simple processing method, this process of producing activated carbon can be easily adapted for large-scale commercial production,” Deshpande added.
To obtain the high surface area activated carbon with porous sheet-like morphology from corn husk, the researchers added KOH as an activating agent. KOH helps in the formation of sheet-like morphology.
The synergy of morphology and high specific surface area (1378 m2 g-1) improve the storage capacity of the activated carbon electrode material.
The storage capability of activated carbon sample tested by using high-operating voltage electrolyte (1M tetraethylammonium tetrafluoroborate (TEABF4) in acetonitrile (AN)). This electrode showed better electrochemical performance (High energy density (20 Wh kg-1) and high-power density (681 W kg-1) at 1 A g-1) than electrodes in conventional supercapacitors.
Explaining further, Dr T. N. Rao, Associate Director, International Advanced Research Centre for Powder Metallurgy and New Materials (ARCI), Hyderabad, added, “Activated carbon derived from natural sources is very promising electrode material for supercapacitors, and the well-known Maxwell company uses coconut-derived activated carbon in their supercapacitors.
“The key scientific challenge in this research is pore size engineering of activated carbon with high surface area and suitable pore size that allows the electrolyte ions to adsorb into pores to the maximum extent which in turn give high capacity. The group at IITH in collaboration with ARCI has succeeded in converting corn husk into high performing activated carbon for supercapacitor application. Cornhusk being widely produced waste, it is also scalable from technology point as well,” Rao added.