Oxygen reduction/evolution activity of air electrodes using nitrogen-doped and perovskite-type oxide-loaded reduced graphene oxides

Oxygen reduction/evolution bi-functional air electrodes with high activity are required for constructing high-performance metal–air secondary batteries. Conventionally, carbon-supported electrocatalysts have been used as the air electrode materials. However, these types of air electrodes have a prob...

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Published inJournal of applied electrochemistry Vol. 49; no. 10; pp. 1055 - 1067
Main Authors Yuasa, Masayoshi, Suenaga, Yuko, Nakamura, Ryushin, Abe, Kenta, Watanabe, Shunsuke
Format Journal Article
LanguageEnglish
Published Dordrecht Springer Netherlands 01.10.2019
Springer Nature B.V
Subjects
Carbon
Carbon black
Catalysis
Catalysts
Chemistry
Chemistry and Materials Science
Doping
Electrocatalysts
Electrochemistry
Electrode materials
Electrodes
Evolution
Fuel cells
Graphene
Industrial Chemistry/Chemical Engineering
Lanthanum compounds
Lanthanum oxides
Nitrogen
Organic compounds
Oxygen evolution reactions
Perovskites
Physical Chemistry
Reduction
Research Article
Storage batteries
Metal–air battery
Oxygen evolution
Oxygen reduction
Reduced graphene oxide
Air electrode
Perovskite-type oxide
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Summary:Oxygen reduction/evolution bi-functional air electrodes with high activity are required for constructing high-performance metal–air secondary batteries. Conventionally, carbon-supported electrocatalysts have been used as the air electrode materials. However, these types of air electrodes have a problem that the carbon black is corroded to water-soluble organic compounds during oxygen evolution reaction. Therefore, we have investigated reduced graphene oxides as an alternative to the conventional carbon black. Cyclic voltammetry in the range of the potential in which the oxygen evolution reaction occurs revealed that the reduced graphene oxide is stable against corrosion during the oxygen evolution reaction. This result indicates that the reduced graphene oxide is a promising candidate electrode material for bi-functional air electrodes. To improve the oxygen reduction and evolution activities of reduced graphene oxides, doping of nitrogen species and loading of perovskite-type oxide catalysts to reduced graphene oxide were examined. It was found that doping of nitrogen species was effective for improving both the oxygen reduction and evolution activity. LaMnO 3 and LaNiO 3 catalysts were effective for improving the oxygen reduction and evolution activities, respectively. The best oxygen reduction and evolution activity was obtained by the LaMnO 3 -loaded nitrogen-doped reduced graphene oxide and LaNiO 3 -loaded nitrogen-doped reduced graphene oxide, respectively. Graphic abstract
ISSN:0021-891X
1572-8838
DOI:10.1007/s10800-019-01350-x