ScholarWorks@동국대학교

초록

Sodium-ion batteries (SIBs) have gained prominence as the ideal choice for next-generation large-scale energy storage systems owing to advantages such as sodium abundance and cost-effectiveness. However, their synthesis requires harsh conditions such as high pressure and temperature, and the cathode materials exhibit poor electrical conductivity and sluggish kinetics, hindering SIBs from meeting the requirements for practical applications. In this study, a conversion-type Gr/FeSO4 nanocomposite based on earth-abundant and environmentally friendly elements was developed using a high-energy mechanical ball-milling method. The conversion reaction in FeSO4 was triggered via a simple direct-contact pre-sodiation method, wherein the FeSO4 particles were reversibly converted to Fe0 and Na2SO4 and recovered in the next charging process. Meanwhile, graphene in Gr/FeSO4 acted as a conductive matrix that provided additional electron transfer paths, resulting in increased ionic and electronic conductivities and enhanced diffusion kinetics. Owing to these matrices, the as-prepared Gr/FeSO4 nanocomposite exhibited remarkable long-term cyclability. This study highlights the advantages of combining pre-sodiation and conversion reactions for cathodes and demonstrates the feasibility of employing naturally abundant FeSO4 for high-performance SIBs.

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