ChemElectroChem (Aug 2024)

Gas Evolution in Li‐Ion Rechargeable Batteries: A Review on Operando Sensing Technologies, Gassing Mechanisms, and Emerging Trends

  • Dr. Tianye Zheng,
  • Dr. Madithedu Muneeswara,
  • Dr. Haihong Bao,
  • Ass. Prof. Jiaqiang Huang,
  • Ass. Prof. Leiting Zhang,
  • Ass. Prof. David S. Hall,
  • Prof. Steven T. Boles,
  • Prof. Wei Jin

DOI
https://doi.org/10.1002/celc.202400065
Journal volume & issue
Vol. 11, no. 15
pp. n/a – n/a

Abstract

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Abstract Gas evolution is fundamentally problematic in rechargeable batteries, and may lead to swelling, smoking, and device‐level failure. In laboratories, monitoring gas evolution can help understand dynamic chemical events inside battery cells, such as the formation of solid‐electrolyte interphases, structural change of electrodes, and electrolyte degradation reactions. However, gassing in commercial batteries, discrete or continuous, is not monitored due to a lack of compatible sensing technologies. Here we describe the working principles of four real‐time gas monitoring technologies for lithium‐ion batteries. Gassing mechanisms and reaction pathways of five major gaseous species, namely H2, C2H4, CO, CO2, and O2, are comprehensively summarized. Since pertinent progress has been made on the optical fiber‐based sensing of strain, pressure, and temperature of various battery cells recently, special emphasis has been given to fiber‐based laser spectroscopy for gas detection. The technical details of the fiber‐enhanced photothermal spectroscopy are compared with the four gas sensing technologies, and the commercialization possibilities are discussed. Owing to its small size, flexibility, and robustness, fiber‐based sensing technology can be compatible with almost all kinds of battery cells, showcasing their great potential in various applications. It is envisioned that gas‐event monitoring of rechargeable cells can be unlocked soon by utilizing fiber‐based gas spectroscopy.

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