1. Simultaneously Generating Redox Mediator and Hybrid SEI for Lithium–oxygen Batteries by Lewis Acid Catalyzed Ring‐opening Reaction of Organic Iodine.
- Author
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Wang, Qian‐Yan, Zheng, Meng‐Ting, Gao, Meng‐Lin, Liao, Ya‐Ling, Zhang, Xiao‐Ping, Fan, Cong, Chen, Wei‐Rong, and Lu, Jun
- Subjects
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LITHIUM-air batteries , *RING-opening reactions , *LEWIS acids , *IODINE , *SULFURIC acid , *LITHIUM cells , *ELECTRIC batteries , *OXIDATION-reduction reaction - Abstract
Facing high overpotential, severe Li corrosion and degradation of electrolytes caused by the reactive oxygen species, the development of lithium–oxygen batteries is seriously limited. Although the iodine species have been considered to be effective redox mediators (RMs) for lowering the charging overpotential, the shuttling of oxidized I3− may attack the Li metal anode, compromising the number of RMs, cycling stability and energy efficiency. Here the intend to introduce 3‐Iodooxetane (C3H5OI, IOD) into TEGDME‐based electrolyte to form a protective SEI layer on the Li surface for defending against the attack of I3−. However, the iodine in IOD is found difficult to dissociate. To solve this problem, hard Lewis acid, aluminum trichloride (AlCl3) is proposed as the catalytic agent for dissociating the I− and triggering the ring‐opening reaction of the detached C3H5O+ ions. The former can dissociate redox couple I3−/I− while the latter can form oligomers or polymers under the attack of a nucleophile. Meanwhile, AlCl3 can form Al2O3 and LiCl inorganic species. Taking together, the introduction of IOD and AlCl3 into electrolytes can effectively derive reduced overpotential and in situ SEI layers consisting of flexible organics and rigid inorganics, endowing lithium–oxygen batteries over 150 cycles with significantly enhanced stability and lifespan. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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