Sustainable Chemistry for the Environment (Aug 2023)

Gum based functional binder for high-performance artificial graphite anode for lithium-ion batteries

  • Joon Ha Chang,
  • Min Wook Pin,
  • Jiman Choi,
  • Jaewon Park,
  • Gyeong Min Choi,
  • Jeongsik Yun,
  • Kie Yong Cho,
  • Zubair Ahmed Chandio,
  • Inhye Kim,
  • Youngjin Kim,
  • Vinod V.T. Padil,
  • Jun Young Cheong

Journal volume & issue
Vol. 2
p. 100012

Abstract

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Artificial graphite (AG), in contrast to natural graphite, has received much attention due to its superior rate capabilities and stability under high current density. Although the rate capabilities can be enhanced by employing artificial graphite, there is room for improvement in the cycle retention characteristics of artificial graphite. In particular, further optimization on the binder type on anodes is necessary, as commercially used polyvinylidene fluoride (PVdF) has limitations in long-term cycling stability. Furthermore, PVdF is dissolved in N-Methyl-2-pyrrolidone (NMP), which is not environmentally- and eco-friendly. In this work, we have introduced a water-soluble binder based on deacetylated kondagogu gum (KG) for AG anodes, which are derived from the gum tree. Upon deacetylation, kondagogu gum can be dissolved in water, which can be directly used together with active materials and conductive agents in a slurry. Replacing a PVdF binder with a KG binder results in an enhanced cycle retention and comparable rate capabilities, without the changes in the overall redox reactions with Li+. Postmortem analysis reveals that the improved electrochemical performance of the AG anode contributed to the excellent structural integrity of the KG binder compared with the PVdF binder.

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