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Showing 1–5 of 5 results
Advanced filters: Author: Ouwei Sheng Clear advanced filters

  • The inactivation of electrodes triggers the loss of capacity and decreases the lifetimes of batteries, especially for high-capacity systems. Here the rejuvenation chemistry for re-activating electrodes, aimed at prolonging the lifetimes of lithium-based batteries and similar energy-storage systems, is discussed. Li, lithium; Cu, copper; e, electrons; RMred, reduced redox mediator; RMox, oxidized redox mediator.

    • Chengbin Jin
    • Ouwei Sheng
    • Xinyong Tao
    Reviews
    Nature Reviews Chemistry
    Volume: 9, P: 553-568

  • Lithium metal electrodes suffer from both chemical and electrochemical corrosion during battery storage and operation. Here, the authors show that lithium corrosion is due to dissolution of the solid-electrolyte interphase and suppress this by utilizing a multifunctional passivation layer.

    • Chengbin Jin
    • Yiyu Huang
    • Xinyong Tao
    ResearchOpen Access
    Nature Communications
    Volume: 14, P: 1-10

  • Inspired by the role of proteins in regulating eggshell mineralization, here Tao, Liu and colleagues apply trifluoroethanol modified eggshell membrane to combat lithium dendrite. Cryo-electron microscopy reveals that the growth along the most favored crystallographic direction is suppressed.

    • Zhijin Ju
    • Jianwei Nai
    • Xinyong Tao
    ResearchOpen Access
    Nature Communications
    Volume: 11, P: 1-10

  • Cycling lithium batteries often results in inactive lithium that no longer participates in redox reactions, leading to performance deterioration. Here the authors use an iodic species to react with inactive lithium, bringing it back to life and thus making batteries last longer.

    • Chengbin Jin
    • Tiefeng Liu
    • Xinyong Tao
    Research
    Nature Energy
    Volume: 6, P: 378-387