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Toward a Lithium-"Air" Battery: The Effect of CO2 on the Chemistry of a Lithium-Oxygen Cell

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Title
Toward a Lithium-"Air" Battery: The Effect of CO2 on the Chemistry of a Lithium-Oxygen Cell
Author(s)
Lim, HK; Lim, HD; Park, KY; Dong-Hwa Seo; Gwon, H; Hong, J; Goddard, WA; Kim, H; Kisuk Kang
Publication Date
2013-07
Journal
JOURNAL OF THE AMERICAN CHEMICAL SOCIETY, v.135, no.26, pp.9733 - 9742
Publisher
AMER CHEMICAL SOC
Abstract
Lithium-oxygen chemistry offers the highest energy density for a rechargeable system as a "lithium-air battery". Most studies of lithium-air batteries have focused on demonstrating battery operations in pure oxygen conditions; such a battery should technically be described as a "lithium-dioxygen battery". Consequently, the next step for the lithium-"air" battery is to understand how the reaction chemistry is affected by the constituents of ambient air. Among the components of air, CO2 is of particular interest because of its high solubility in organic solvents and it can react actively with O-2(-center dot), which is the key intermediate species in Li-O-2 battery reactions. In this work, we investigated the reaction mechanisms in the Li-O-2/CO2 cell under various electrolyte conditions using quantum mechanical simulations combined with experimental verification. Our most important finding is that the subtle balance among various reaction pathways influencing the potential energy surfaces can be modified by the electrolyte solvation effect Thus, a low dielectric electrolyte tends to primarily form Li2O2, while a high dielectric electrolyte is effective in electrochemically activating CO2, yielding only Li2CO3. Most surprisingly, we further discovered that a high dielectric medium such as DMSO can result in the reversible reaction of Li2CO3 over multiple cycles. We believe that the current mechanistic understanding of the chemistry of CO2 in a Li-air cell and the interplay of CO2 with electrolyte solvation will provide an important guideline for developing Li-air batteries. Furthermore, the possibility for a rechargeable Li-O-2/CO2 battery based on Li2CO3 may have merits in enhancing cyclability by minimizing side reactions © 2013 American Chemical Society
URI
https://pr.ibs.re.kr/handle/8788114/4868
DOI
10.1021/ja4016765
ISSN
0002-7863
Appears in Collections:
Center for Nanoparticle Research(나노입자 연구단) > 1. Journal Papers (저널논문)
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