南方科技大学知识苑(SUSTech KC): Electronic regulation & improved conductivity of molecular catalysts as electrocatalysts

题名	Electronic regulation & improved conductivity of molecular catalysts as electrocatalysts
作者	Hu, Bihua 1,2; Cao, Hailin3 ; Lei, Zhiwei1 ; Cui, Shuyu 1 ; Wang, Peizhi1 ; Tang, Jun 2; Wang, Xingzhu1,4 ; Xu, Baomin1
通讯作者	Tang, Jun; Wang, Xingzhu; Xu, Baomin
发表日期	2024-07-01
DOI	10.1039/d4cy00431k
发表期刊	CATALYSIS SCIENCE & TECHNOLOGY 影响因子和分区
ISSN	2044-4753
EISSN	2044-4761
摘要	["Molecular catalysts with well-designed structures and abundant metal-nitrogen active sites have received a lot of attention for effective electroreduction of carbon dioxide (ERCD) due to the advantages of having clearly defined active sites for mechanism investigations. However, this metal-nitrogen combination with a fixed electronic structure severely restricts the catalytic efficiency and selectivity, resulting in low production efficiency of more valuable compounds. This work presents the synthesis of metal macrocyclic compounds MPc (M = Fe, Co, Ni, and Zn) through in situ anodic oxidation of N-doped Ti3C2Tx (N-MXene) nanosheets with anchored MPc nanoparticles (named MPc/o-N-MXene). The resulting catalysts exhibit high activity and moreover tailorable selectivity for ERCD on CoPc; CoPc/o-N-MXene shows a faradaic efficiency (FE) for methanol as high as 39.0% with a current density of 32.7 mA cm-2 at -1.0 V (vs. RHE). The oxidation process creates a significant contact between the M-N4 active sites and N-MXene, which regulates the selectivity of ERCD. DFT calculations suggest that only the electronic regulation of Co-N4 by N-doped MXene supports the creation of intermediate *HCO in the generation of methanol in ERCD. Our study presents a new route for the synthesis of efficient catalysts and provides a comprehensive perspective on the mechanism of ERCD on MPc.","Molecular catalysts supported by N-MXene with in situ oxidation have been synthesized by a simple method. Among them, CoPc/o-N-MXene exhibits superior activity and selectivity for ERCD to methanol."]
相关链接	[来源记录]
收录类别	SCI ; EI
语种	英语
学校署名	第一 ; 通讯
资助项目	Key Fundamental Research Project funding from the Shenzhen Science and Technology Innovation Committee["JCYJ20200109141014474","JCYJ20220818100406014"] ; National Natural Science Foundation of China[U19A2089]
WOS研究方向	Chemistry
WOS类目	Chemistry, Physical
WOS记录号	WOS:001267902100001
出版者	ROYAL SOC CHEMISTRY
来源库	Web of Science
引用统计
成果类型	期刊论文
条目标识符	http://sustech.caswiz.com/handle/2SGJ60CL/789852
专题	工学院_材料科学与工程系工学院_机械与能源工程系
作者单位	1.Southern Univ Sci & Technol, Dept Mat Sci & Engn, Shenzhen 518055, Peoples R China 2.Shenzhen Technol Univ, Coll New Mat & New Energies, Shenzhen 518118, Peoples R China 3.Southern Univ Sci & Technol, Dept Mech & Energy Engn, Shenzhen 518055, Peoples R China 4.Shenzhen Putai Technol Co Ltd, Shenzhen 518055, Peoples R China
第一作者单位	材料科学与工程系
通讯作者单位	材料科学与工程系
第一作者的第一单位	材料科学与工程系
推荐引用方式 GB/T 7714	Hu, Bihua,Cao, Hailin,Lei, Zhiwei,et al. Electronic regulation & improved conductivity of molecular catalysts as electrocatalysts[J]. CATALYSIS SCIENCE & TECHNOLOGY,2024.
APA	Hu, Bihua.,Cao, Hailin.,Lei, Zhiwei.,Cui, Shuyu.,Wang, Peizhi.,...&Xu, Baomin.(2024).Electronic regulation & improved conductivity of molecular catalysts as electrocatalysts.CATALYSIS SCIENCE & TECHNOLOGY.
MLA	Hu, Bihua,et al."Electronic regulation & improved conductivity of molecular catalysts as electrocatalysts".CATALYSIS SCIENCE & TECHNOLOGY (2024).