Carbon composites from iron-chelating pyridine nitrogen-rich coordinated nanosheets for oxygen reduction

Bing Zhang, Hele Guo, Longsheng Zhang, Xu Zhang, Chao Zhang, Tianxi Liu
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Abstract

The exploration of a noble-metal-free and nitrogen-doped carbon (M–N/C) composite electrocatalyst for the oxygen reduction reaction (ORR) remains a great challenge. The activities of the M–N/C composite electrocatalysts are mainly affected by the metal active sites, pyridinic nitrogen, and graphitic nitrogen. In the present work, the iron-coordinated self-assembly is proposed for the preparation of iron-chelating pyridine nitrogen-rich coordinated nanosheet (IPNCN) composites as electrocatalysts. Due to the highly conjugated structure of the IPNCN precursor, the pyridine nitrogen elements at both ends of the tetrapyrido [3,2-a:2',3'-c:3'',2''-h:2''',3'''-j] phenazine (TP) provide the multiple ligands, and the coordination interactions between the irons and the pyridine nitrogen further improve the thermodynamic stability, where the metal active sites and nitrogen elements are uniformly distributed in the whole structure. The resultant IPNCN composites exhibit excellent ORR performance with an onset potential of 0.93 V and a half potential of 0.84 V. Furthermore, the IPNCN composite electrocatalysts show the higher methanol resistance and electrochemical durability than the commercial Pt/C catalysts. It could be convinced that the as-designed IPNCN composite catalysts would be a promising alternative to the noble metal Pt-based catalysts in the practical applications.

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氧还原用铁螯合吡啶富氮配位纳米片碳复合材料
探索无贵金属和掺氮碳(M-N /C)复合电催化剂用于氧还原反应(ORR)仍然是一个巨大的挑战。M-N /C复合电催化剂的活性主要受金属活性位、吡啶氮和石墨氮的影响。本文提出用铁配位自组装法制备铁螯合吡啶富氮配位纳米片复合材料作为电催化剂。由于IPNCN前驱体的高共轭结构,四吡啶[3,2-a:2',3'-c:3'',2' -h:2'',3'' -j]吩嗪(TP)两端的吡啶氮元素提供了多重配体,铁与吡啶氮之间的配位相互作用进一步提高了热力学稳定性,金属活性位点和氮元素均匀分布在整个结构中。所得的IPNCN复合材料表现出优异的ORR性能,起始电位为0.93 V,半电位为0.84 V。此外,IPNCN复合电催化剂表现出比商用Pt/C催化剂更高的耐甲醇性能和电化学耐久性。可以相信,所设计的IPNCN复合催化剂在实际应用中有望取代贵金属pt基催化剂。
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