Litcius/Paper detail

Ethanol-derived graphene by microwave plasma torch as efficient cathode for Li-S batteries with ultralong cycle life

Jesús M. Blázquez‐Moreno, Francisco Javier Morales‐Calero, Antonio Cobos‐Luque, Andrés M. Raya, Rocío Rincón, Almudena Benítez, Álvaro Caballero

2025Journal of Power Sources11 citationsDOIOpen Access PDF

Abstract

High-quality graphene derived from ethanol (EdG) using an atmospheric pressure plasma torch has been used for the first time as a sulfur host for lithium-sulfur (Li-S) battery cathodes. Its excellent structural, morphological, and conductive properties make it a suitable material to accommodate sulfur inside its pores. In this way, the shuttle effect is effectively alleviated, reducing the loss of capacity, and improving the lifespan of Li-S batteries. EdG@S-based cathodes have demonstrated excellent performance for use in this technology, showing ultra-high stability, reaching 1000 cycles at very high rates of 3C and 5C, with minimal capacity loss (0.064 % and 0.045 % per cycle, respectively). In addition, a remarkable specific capacity of 256 mAh/g at ultra-high rates of up to 10C is achieved. Therefore, this study demonstrates that the use of ethanol-derived graphene synthesised by microwave plasma can be a viable option for the development, scalability, and industrialisation of Li-S battery technology. • High-quality graphene cathode derived from ethanol decomposition using a microwave plasma torch. • Incorporation of sulfur via melt-diffusion method preserves graphene morphology. • First-ever use of ethanol-derived graphene (EdG) by the TIAGO torch for Li-S cells. • Ultra-high rate capability and long-term stability are demonstrated in LSBs.

Topics & Concepts

GrapheneCathodeMaterials scienceMicrowavePlasmaTorchNanotechnologyPlasma torchChemistryMetallurgyComputer sciencePhysicsTelecommunicationsPhysical chemistryWeldingQuantum mechanicsAdvancements in Battery MaterialsAdvanced Battery Materials and TechnologiesExtraction and Separation Processes