Low-cost and efficient oxygen reduction reaction(ORR)electrocatalysts are the key to developing Zn-air batteries for renewable energy storage.Herein,the Mn-N-P doped carbon sphere was prepared through polymerization o...Low-cost and efficient oxygen reduction reaction(ORR)electrocatalysts are the key to developing Zn-air batteries for renewable energy storage.Herein,the Mn-N-P doped carbon sphere was prepared through polymerization of hexachlorotripolyphosphazene(HCCP)and phloroglucinol,and then followed the calcination at 900°C.Theory calculations demonstrated the introduction of Mn in N-P doped carbon could lower the dissociation barrier of O2into O*and promote the ORR through a 4e-pathway.The asprepared catalysts exhibited a half-wave potential of 0.82 V vs.RHE and limiting current density of 5.2 m A/cm^(2)toward ORR,which was comparable to those of the commercial Pt/C catalysts.In addition,Zn-air batteries with 0.05 Mn-N-P-C catalysts showed a high specific capacity of 830 m Ah/gZnand excellent cycle stability.This facile approach demonstrated herein could be a solution to develop optimum non-precious metal catalysts for the application in cathodes of proton exchange membrane fuel cells.This study also provides new insight to design the catalysts of multi-heteroatom coordinated metal in the carbon matrix for both fundamental researches and practical applications.展开更多
基金financially supported by the Science and Technology Program of University of Jinan(Nos.XKY2103,XKY2105)National Natural Science Foundation of China(Nos.51902130,52072085)Key Research and Development project of Shandong Province(No.2019GGX102087)。
文摘Low-cost and efficient oxygen reduction reaction(ORR)electrocatalysts are the key to developing Zn-air batteries for renewable energy storage.Herein,the Mn-N-P doped carbon sphere was prepared through polymerization of hexachlorotripolyphosphazene(HCCP)and phloroglucinol,and then followed the calcination at 900°C.Theory calculations demonstrated the introduction of Mn in N-P doped carbon could lower the dissociation barrier of O2into O*and promote the ORR through a 4e-pathway.The asprepared catalysts exhibited a half-wave potential of 0.82 V vs.RHE and limiting current density of 5.2 m A/cm^(2)toward ORR,which was comparable to those of the commercial Pt/C catalysts.In addition,Zn-air batteries with 0.05 Mn-N-P-C catalysts showed a high specific capacity of 830 m Ah/gZnand excellent cycle stability.This facile approach demonstrated herein could be a solution to develop optimum non-precious metal catalysts for the application in cathodes of proton exchange membrane fuel cells.This study also provides new insight to design the catalysts of multi-heteroatom coordinated metal in the carbon matrix for both fundamental researches and practical applications.
