Oxidation Stability of Organic Redox Mediators as Mobile Catalysts in Lithium-Oxygen Batteries

Won Jin Kwak; Jiwon Park; Hun Kim; Jung Min Joo; Doron Aurbach; Hye Ryung Byon; Yang Kook Sun

doi:10.1021/acsenergylett.0c00883

Oxidation Stability of Organic Redox Mediators as Mobile Catalysts in Lithium-Oxygen Batteries

Won Jin Kwak, Jiwon Park, Hun Kim, Jung Min Joo, Doron Aurbach, Hye Ryung Byon, Yang Kook Sun

Department of Chemistry

Research output: Contribution to journal › Article › peer-review

34 Scopus citations

Abstract

Employing organic redox mediators (ORMs) for lithium-oxygen (Li-O2) batteries has emerged as an important strategy to suppress charging overpotentials. Judicious molecular designs of ORMs can also tailor their redox potential and electron-transfer rate to optimize the catalytic efficiency. However, the stability of ORMs in Li-O2 cells was scarcely studied. Here, the catalytic efficiency and stability of several important ORMs are assessed through in situ gas analysis and reactivity tests with singlet oxygen. Some well-known ORMs are detrimentally decomposed during the first cycle in Li-O2 cells, whereas nitroxyl-radical-based ORMs bear the most stable and efficient response. Analogous nitroxyl-radical derivatives further increase round-trip energy efficiency and electron-transfer kinetics. This study underlines chemical stability aspects of ORMs, which are mandatory for the long-term cyclability in Li-O2 cells. We emphasize that besides the importance of ORMs in these systems and their proper selection, an effective operation of Li-O2 cells depends also strongly on the stability of the carbonaceous cathodes and the electrolyte solutions. The stability of all the components in these systems is inter-related.

Original language	English
Pages (from-to)	2122-2129
Number of pages	8
Journal	ACS Energy Letters
Volume	5
Issue number	6
DOIs	https://doi.org/10.1021/acsenergylett.0c00883
State	Published - 12 Jun 2020

Bibliographical note

Publisher Copyright:
© 2020 American Chemical Society.

Funding

This work was supported by the Samsung Research Funding & Incubation Center of Samsung Electronics under Project SRFC-MA1702-05 and the Human Resources Development Program (No. 20184010201720) of a Korea Institute of Energy Technology Evaluation and Planning (KETEP) grant funded by the Ministry of Trade, Industry and Energy of the Korean government.

Funders	Funder number
Human Resources Development program	20184010201720
Samsung	SRFC-MA1702-05
Ministry of Trade, Industry and Energy
Korea Institute of Energy Technology Evaluation and Planning

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This output contributes to the following UN Sustainable Development Goals (SDGs)

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abstract = "Employing organic redox mediators (ORMs) for lithium-oxygen (Li-O2) batteries has emerged as an important strategy to suppress charging overpotentials. Judicious molecular designs of ORMs can also tailor their redox potential and electron-transfer rate to optimize the catalytic efficiency. However, the stability of ORMs in Li-O2 cells was scarcely studied. Here, the catalytic efficiency and stability of several important ORMs are assessed through in situ gas analysis and reactivity tests with singlet oxygen. Some well-known ORMs are detrimentally decomposed during the first cycle in Li-O2 cells, whereas nitroxyl-radical-based ORMs bear the most stable and efficient response. Analogous nitroxyl-radical derivatives further increase round-trip energy efficiency and electron-transfer kinetics. This study underlines chemical stability aspects of ORMs, which are mandatory for the long-term cyclability in Li-O2 cells. We emphasize that besides the importance of ORMs in these systems and their proper selection, an effective operation of Li-O2 cells depends also strongly on the stability of the carbonaceous cathodes and the electrolyte solutions. The stability of all the components in these systems is inter-related.",

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AU - Byon, Hye Ryung

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AB - Employing organic redox mediators (ORMs) for lithium-oxygen (Li-O2) batteries has emerged as an important strategy to suppress charging overpotentials. Judicious molecular designs of ORMs can also tailor their redox potential and electron-transfer rate to optimize the catalytic efficiency. However, the stability of ORMs in Li-O2 cells was scarcely studied. Here, the catalytic efficiency and stability of several important ORMs are assessed through in situ gas analysis and reactivity tests with singlet oxygen. Some well-known ORMs are detrimentally decomposed during the first cycle in Li-O2 cells, whereas nitroxyl-radical-based ORMs bear the most stable and efficient response. Analogous nitroxyl-radical derivatives further increase round-trip energy efficiency and electron-transfer kinetics. This study underlines chemical stability aspects of ORMs, which are mandatory for the long-term cyclability in Li-O2 cells. We emphasize that besides the importance of ORMs in these systems and their proper selection, an effective operation of Li-O2 cells depends also strongly on the stability of the carbonaceous cathodes and the electrolyte solutions. The stability of all the components in these systems is inter-related.

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Oxidation Stability of Organic Redox Mediators as Mobile Catalysts in Lithium-Oxygen Batteries

Abstract

Bibliographical note

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