Atomic‐Scale Cryo‐TEM Studies of the Electrochemistry of Redox Mediator in Li–O2 Batteries

Rechargeable aprotic lithium (Li)‐oxygen battery (LOB) is a potential next‐generation energy storage technology because of its high theoretical specific energy. However, the role of redox mediator on the oxide electrochemistry remains unclear. This is partly due to the intrinsic complexity of the ba...

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Published in:Small (Weinheim an der Bergstrasse, Germany) Germany), 2024-07, Vol.20 (30), p.e2311739-n/a
Main Authors: Gao, Zhiying, Yao, Jingming, Yan, Jitong, Sun, Jun, Du, Congcong, Dai, Qiushi, Su, Yong, Zhao, Jun, Chen, Jingzhao, Li, Xiaomei, Li, Hui, Zhang, Pan, Ma, Jun, Qiu, Hailong, Zhang, Liqiang, Tang, Yongfu, Huang, Jianyu
Format: Article
Language:English
Subjects:
Anodic protection
Chemical reduction
Complexity
Cryo‐TEM
Decomposition reactions
Electrochemistry
Electrolytes
Energy storage
LiOH
Lithium
Li–O2 batteries
Oxygen reduction reactions
Rechargeable batteries
redox mediator
Specific energy
Transmission electron microscopy
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Summary:Rechargeable aprotic lithium (Li)‐oxygen battery (LOB) is a potential next‐generation energy storage technology because of its high theoretical specific energy. However, the role of redox mediator on the oxide electrochemistry remains unclear. This is partly due to the intrinsic complexity of the battery chemistry and the lack of in‐depth studies of oxygen electrodes at the atomic level by reliable techniques. Herein, cryo‐transmission electron microscopy (cryo‐TEM) is used to study how the redox mediator LiI affects the oxygen electrochemistry in LOBs. It is revealed that with or without LiI in the electrolyte, the discharge products are plate‐like LiOH or toroidal Li2O2, respectively. The I2 assists the decomposition of LiOH via the formation of LiIO3 in the charge process. In addition, a LiI protective layer is formed on the Li anode surface by the shuttle of I3−, which inhibits the parasitic Li/electrolyte reaction and improves the cycle performance of the LOBs. The LOBs returned to 2e− oxygen reduction reaction (ORR) to produce Li2O2 after the LiI in the electrolyte is consumed. This work provides new insight on the role of redox mediator on the complex electrochemistry in LOBs which may aid the design LOBs for practical applications. The role of redox mediator in lithium oxygen batteries is studied by cryo‐transmission electron microscopy. The discharge products are toroid‐shaped Li2O2 without LiI additive in electrolyte. The discharge products are plate‐like LiOH with LiI additive in electrolyte, and a LiI protective layer is formed on the anode surface that improves the cycle performance of the LOBs.
ISSN:1613-6810
1613-6829
1613-6829
DOI:10.1002/smll.202311739