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Graphene is a single layer of Carbon atoms arranged in two-dimensional honeycomb lattice (Pic Via Wikipedia)
Indian scientists have developed a new low-cost method for upscaling of production of graphene while preserving its single layered properties.
The new method is likely to reduce the cost of producing Graphene, which is the thinnest, strongest and most conductive material in the world.
Graphene is one-atom-thick sheet of carbon atoms, which has huge potential in energy storage, coatings, sensors as well as superconductivity.
However, Graphene is difficult to produce while retaining its single layered properties.
"Researchers from Jawaharlal Nehru Centre for Advanced Scientific Research (JNCASR)... through their recent research work have upscaled graphene production while retaining its thin layered properties," the Ministry of Science and Technology said in a statement on Saturday (26 September).
"This was made possible by a simple, affordable method wherein naphthalene coated nickel foil was heated for a few minutes in an ordinary vacuum by joule heating and was cooled to get twisted layers of graphene," the ministry said.
In the research by Nikita Gupta and Professor G U Kulkarni published in the ‘Journal of Physical Chemistry Letters’, the scientists have also defined a formula to quantify how much single layer like behaviour exists in such a system.
The twisted system has multiple layers, each behaving like a single layer, allows variation in the experimental data within one sample, thus making quantification possible to achieve. The derived formula provides an insight into any twisted hexagonal multilayer system and may be used to tune superconductivity.
The researchers used a combination of two techniques - Raman Scattering and Electron Diffraction - to understand and quantify how much single layer like behaviour exists in the graphene system, the ministry said.
Observing fascinating properties of twisted multilayer graphene such as visible absorption band, efficient corrosion resistance, temperature-dependent transport, influencing the crystalline orientation of source material, helped the JNCASR team to understand the landscape of the given twisted multilayer graphene system, it added.