Construction of high–loading 3D CoNC catalyst for oxygen reduction reaction in Zn–air batteries

[Display omitted] •3D CoNC (NGH + PPY) was prepared by oxidation polymerization followed by pyrolysis.•3D CoNC (NGH + PPY) possesses high–loading Co single atom.•3D CoNC (NGH + PPY) shows 3D architecture, large SSA and enriched mesopores.•3D CoNC (NGH + PPY) exhibits much improved ORR performance.•3...

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Published inJournal of electroanalytical chemistry (Lausanne, Switzerland) Vol. 935
Main Authors Li, Huaiyu, Xu, Chenxi, Wang, Wei, Li, Gangyong, Huang, Junlin, Chen, Liang, Hou, Zhaohui
Format Journal Article
LanguageEnglish
Published Elsevier B.V 15.04.2023
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Summary:[Display omitted] •3D CoNC (NGH + PPY) was prepared by oxidation polymerization followed by pyrolysis.•3D CoNC (NGH + PPY) possesses high–loading Co single atom.•3D CoNC (NGH + PPY) shows 3D architecture, large SSA and enriched mesopores.•3D CoNC (NGH + PPY) exhibits much improved ORR performance.•3D CoNC (NGH + PPY) presents excellent electrochemical performance in ZABs. The development of single atom catalysts is considered as a hotspot in the field of electrocatalysis. As the representative of single atom catalysts, metal and nitrogen co–doped carbon (MNC) attracts worldwide attentions due to its great potential in the application of oxygen reduction reaction (ORR). However, the actual preparation of MNC still confronts with tedious procedure, harsh condition and relatively low loading of single metal atom. In this work, we successfully prepare high–loading 3D CoNC architecture by a facile oxidation polymerization followed by pyrolysis process employing 3D nitrogen–doped graphene hydrogel (NGH) and pyrrole (PY) as the reaction precursors. Benefitting from the individual advantages of 3D NGH and PY, the resultant 3D CoNC possesses unique 3D architecture, high–loading single Co atom (2.74 wt%), large specific surface area and enriched mesopores, which benefit the exposure of sufficient catalytic sites and facilitate electrons transfer and ions transport, thus generating much enhanced ORR performance. When used as the cathode catalyst for zinc–air batteries (ZABs), it shows comparable performance with commercial Pt/C catalyst. Clearly, our finding offers a good guidance on the design and synthesis of advanced high–loading single atom catalysts.
ISSN:1572-6657
1873-2569
DOI:10.1016/j.jelechem.2023.117316