Ethyl Viologen as a Superoxide Quencher to Enhance the Oxygen Reduction Reaction in Li-O2 Batteries

Sisi Wu; Jing Yang; Ning Qin; Yingzhi Li; Haiou Wang; Yong-Wei Zhang; Qing Wang; Zhouguang Lu

doi:10.1021/acsaem.2c01501

Ethyl Viologen as a Superoxide Quencher to Enhance the Oxygen Reduction Reaction in Li-O₂ Batteries

Sisi Wu, Jing Yang, Ning Qin, Yingzhi Li, Haiou Wang, Yong-Wei Zhang^*, Qing Wang^*, Zhouguang Lu^*

^*Corresponding author for this work

Department of Mechanical Engineering

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

4 Citations (Scopus)

Abstract

LiO₂ is a critical intermediate of oxygen reduction reaction in nonaqueous Li-O₂ batteries that largely determines the discharge capacity and cycling stability. Currently, functional redox mediators that can promote the solution reaction route by enhancing the solvation of LiO₂ have attracted tremendous interest to increase the attainable capacity. Conversely, redox mediators that quench LiO₂ and facilitate the surface reaction route receive little attention. Here, we provide an in-depth exploration of the catalytic pathway and effect of a superoxide quencher that modulates the surface growth of Li₂O₂. Surprisingly, the predomination of the surface reaction route by ethyl viologen helps deliver a capacity as much as that promoted by the solution reaction route. The findings of this work provide a new direction of screening and evaluating functioning redox mediators for Li-O₂ batteries.

Original language	English
Pages (from-to)	9040-9048
Journal	ACS Applied Energy Materials
Volume	5
Issue number	7
Online published	6 Jul 2022
DOIs	https://doi.org/10.1021/acsaem.2c01501
Publication status	Published - 25 Jul 2022

Research Keywords

Li-O2 batteries
redox mediator
oxygen reduction reaction
LiO2 intermediate
catalysis
INITIO MOLECULAR-DYNAMICS
TOTAL-ENERGY CALCULATIONS
ELECTROLYTES
EFFICIENCY
STABILITY
TRANSPORT
DISCHARGE
CATALYSTS

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title = "Ethyl Viologen as a Superoxide Quencher to Enhance the Oxygen Reduction Reaction in Li-O2 Batteries",

abstract = "LiO2 is a critical intermediate of oxygen reduction reaction in nonaqueous Li-O2 batteries that largely determines the discharge capacity and cycling stability. Currently, functional redox mediators that can promote the solution reaction route by enhancing the solvation of LiO2 have attracted tremendous interest to increase the attainable capacity. Conversely, redox mediators that quench LiO2 and facilitate the surface reaction route receive little attention. Here, we provide an in-depth exploration of the catalytic pathway and effect of a superoxide quencher that modulates the surface growth of Li2O2. Surprisingly, the predomination of the surface reaction route by ethyl viologen helps deliver a capacity as much as that promoted by the solution reaction route. The findings of this work provide a new direction of screening and evaluating functioning redox mediators for Li-O2 batteries.",

keywords = "Li-O2 batteries, redox mediator, oxygen reduction reaction, LiO2 intermediate, catalysis, INITIO MOLECULAR-DYNAMICS, TOTAL-ENERGY CALCULATIONS, ELECTROLYTES, EFFICIENCY, STABILITY, TRANSPORT, DISCHARGE, CATALYSTS",

author = "Sisi Wu and Jing Yang and Ning Qin and Yingzhi Li and Haiou Wang and Yong-Wei Zhang and Qing Wang and Zhouguang Lu",

year = "2022",

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TY - JOUR

T1 - Ethyl Viologen as a Superoxide Quencher to Enhance the Oxygen Reduction Reaction in Li-O2 Batteries

AU - Wu, Sisi

AU - Yang, Jing

AU - Qin, Ning

AU - Li, Yingzhi

AU - Wang, Haiou

AU - Zhang, Yong-Wei

AU - Wang, Qing

AU - Lu, Zhouguang

PY - 2022/7/25

Y1 - 2022/7/25

N2 - LiO2 is a critical intermediate of oxygen reduction reaction in nonaqueous Li-O2 batteries that largely determines the discharge capacity and cycling stability. Currently, functional redox mediators that can promote the solution reaction route by enhancing the solvation of LiO2 have attracted tremendous interest to increase the attainable capacity. Conversely, redox mediators that quench LiO2 and facilitate the surface reaction route receive little attention. Here, we provide an in-depth exploration of the catalytic pathway and effect of a superoxide quencher that modulates the surface growth of Li2O2. Surprisingly, the predomination of the surface reaction route by ethyl viologen helps deliver a capacity as much as that promoted by the solution reaction route. The findings of this work provide a new direction of screening and evaluating functioning redox mediators for Li-O2 batteries.

AB - LiO2 is a critical intermediate of oxygen reduction reaction in nonaqueous Li-O2 batteries that largely determines the discharge capacity and cycling stability. Currently, functional redox mediators that can promote the solution reaction route by enhancing the solvation of LiO2 have attracted tremendous interest to increase the attainable capacity. Conversely, redox mediators that quench LiO2 and facilitate the surface reaction route receive little attention. Here, we provide an in-depth exploration of the catalytic pathway and effect of a superoxide quencher that modulates the surface growth of Li2O2. Surprisingly, the predomination of the surface reaction route by ethyl viologen helps deliver a capacity as much as that promoted by the solution reaction route. The findings of this work provide a new direction of screening and evaluating functioning redox mediators for Li-O2 batteries.

KW - Li-O2 batteries

KW - redox mediator

KW - oxygen reduction reaction

KW - LiO2 intermediate

KW - catalysis

KW - INITIO MOLECULAR-DYNAMICS

KW - TOTAL-ENERGY CALCULATIONS

KW - ELECTROLYTES

KW - EFFICIENCY

KW - STABILITY

KW - TRANSPORT

KW - DISCHARGE

KW - CATALYSTS

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U2 - 10.1021/acsaem.2c01501

DO - 10.1021/acsaem.2c01501

M3 - RGC 21 - Publication in refereed journal

SN - 2574-0962

VL - 5

SP - 9040

EP - 9048

JO - ACS Applied Energy Materials

JF - ACS Applied Energy Materials

IS - 7

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