1. Identification of active sites for acidic oxygen reduction on carbon catalysts with and without nitrogen doping
- Author
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Jia, Yi, Zhang, Longzhou, Zhuang, Linzhou, Liu, Hongli, Yan, Xuecheng, Wang, Xin, Liu, Jiandang, Wang, Jiancheng, Zheng, Yarong, Xiao, Zhaohui, Taran, Elena, Chen, Jun, Yang, Dongjiang, Zhu, Zhonghua, Wang, Shuangyin, Dai, Liming, Yao, Xiangdong, Jia, Yi, Zhang, Longzhou, Zhuang, Linzhou, Liu, Hongli, Yan, Xuecheng, Wang, Xin, Liu, Jiandang, Wang, Jiancheng, Zheng, Yarong, Xiao, Zhaohui, Taran, Elena, Chen, Jun, Yang, Dongjiang, Zhu, Zhonghua, Wang, Shuangyin, Dai, Liming, and Yao, Xiangdong
- Abstract
Owing to the difficulty in controlling the dopant or defect types and their homogeneity in carbon materials, it is still a controversial issue to identify the active sites of carbon-based metal-free catalysts. Here we report a proof-of-concept study on the active-site evaluation for a highly oriented pyrolytic graphite catalyst with specific pentagon carbon defective patterns (D-HOPG). It is demonstrated that specific carbon defect types (an edged pentagon in this work) could be selectively created via controllable nitrogen doping. Work-function analyses coupled with macro and micro-electrochemical performance measurements suggest that the pentagon defects in D-HOPG served as major active sites for the acidic oxygen reduction reaction, even much superior to the pyridinic nitrogen sites in nitrogen-doped highly oriented pyrolytic graphite. This work enables us to elucidate the relative importance of the specific carbon defects versus nitrogen-dopant species and their respective contributions to the observed overall acidic oxygen reduction reaction activity.
- Published
- 2019