Multifunctional Dipoles Enabling Enhanced Ionic and Electronic Transport for High‑Energy Batteries (IMAGE)

Shanghai Jiao Tong University Journal Center

Multifunctional Dipoles Enabling Enhanced Ionic and Electronic Transport for High‑Energy Batteries

Caption

  • Offers a thorough review on the mechanism of molecular and ion dipoles in high-energy batteries, covering development, classification, and multifaceted roles in battery systems.
  • Elucidates how molecular and ion dipoles regulate ionic transport, optimize solvation structures, strengthen the electric double layer, and construct stable solid electrolyte interphase/cathode–electrolyte interface layers, all of which boost battery performance.
  • Demonstrates the wide-ranging applications of dipole interactions in various battery systems, such as suppressing dendrites in lithium–metal batteries and improving the cycling stability of lithium–sulfur batteries.
  • Proposes future research directions including AI-assisted materials design, in-depth mechanism exploration, multidisciplinary integration, database establishment, and promoting practical applications, aiming to drive the development of high-energy batteries.

Credit

Shihai Cao, Yuntong Sun*, Yinghao Li, Ao Wang, Wenyao Zhang, Zhendong Hao*, Jong-Min Lee*.

Usage Restrictions

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License

CC BY-NC-ND

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