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崔淼

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Gender:Female
Alma Mater:大连理工大学
Degree:Doctoral Degree
School/Department:化学学院
Business Address:校部化学楼434
Contact Information:0411-84706292
E-Mail:mcui@dlut.edu.cn
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Current position: Home >> Scientific Research >> Paper Publications

Morphology engineering of cobalt embedded in nitrogen doped porous carbon as bifunctional oxygen electrocatalyst for Zn-air battery

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Indexed by:期刊论文

Date of Publication:2021-02-02

Journal:MATERIALS TODAY ENERGY

Volume:17

ISSN No.:2468-6069

Key Words:Bifunctional catalyst; Oxygen evolution reaction; Oxygen reduction reaction; Metal complex; Morphology effect

Abstract:The structure and morphology of catalysts can affect their catalytic performance due to the various exposed active sites and mass transport pathway. Herein, we synthesis a serious of Co-based complex with spindle-like, branched spindle, disk-like and quasi-sphere morphologies and found that the crystal growth is controlled by multistep crystal splitting mechanism. We further transferred the Co-based complex into Co embedded in nitrogen doped porous carbon (Co@NC) by thermal annealing to investigate the morphology effect of electrocatalysts. It was found the catalytic performance of the catalysts exhibits a trend of quasi-sphere (Co@NC-80) > spindle-like (Co@NC-300) > branched spindle (Co@NC-200) > disk-like (Co@NC-130), probably due to the various exposed efficient active sites of the catalyst induced by their morphology, and various mass transport resistance in the catalysts. Impressively, the Co@NC-80 exhibits comparable ORR (oxygen reduction reaction) activity with Pt/C and better OER (oxygen evolution reaction) activity than RuO2, highlighting its bifunctional catalytic performance for metal-air batteries. The Zn-air catalyzed by Co@NC-80 exhibits an open circuit voltage of 1.35 V, a high specific capacity of 887.5 mA h/g and a max power density of 168.7 mW cm(-2), as well as excellent long-time stability with no obvious performance decay after charge-discharge cycling of 140 h. (C) 2020 Elsevier Ltd. All rights reserved.