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Passivating Lithiated Graphite via Targeted Repair of SEI to Inhibit Exothermic Reactions in Early-Stage of Thermal Runaway for Safer Lithium-Ion Batteries.

Yuanke K WuZiqi Q ZengSheng LeiMengchuang C LiuWei ZhongMingsheng S QinShijie J ChengJia Xie
Published in: Angewandte Chemie (International ed. in English) (2023)
The self-exothermic in early stage of thermal runaway (TR) is blasting-fuse for Li-ion battery safety issues. The exothermic reaction between lithiated graphite (LiC x ) and electrolyte accounts for onset of this behavior. However, preventing the deleterious reaction still encounters hurdles. Here, we manage to inhibit this reaction by passivating LiC x in real time via targeted repair of SEI. It is shown that 1,3,5-trimethyl-1,3,5-tris(3,3,3-trifluoropropyl)cyclotrisiloxane (D 3 F) can be triggered by LiC x to undergo ring-opening polymerization at elevated temperature, so as to targeted repair of fractured SEI. Due to the high thermal stability of polymerized D 3 F, exothermic reaction between LiC x and electrolyte is inhibited. As a result, the self-exothermic and TR trigger temperatures of pouch cell are increased from 159.6 and 194.2 °C to 300.5 and 329.7 °C. This work opens up a new avenue for designing functional additives to block initial exothermal reaction and inhibit TR in early stage.
Keyphrases
  • early stage
  • cancer therapy
  • ionic liquid
  • sentinel lymph node
  • single cell
  • solid state
  • electron transfer
  • ion batteries
  • drug delivery
  • radiation therapy
  • bone marrow
  • mesenchymal stem cells