Anchoring zero valence single atoms of nickel and iron on graphdiyne for hydrogen evolution

Yurui Xue; Bolong Huang; Yuanping Yi; Yuan Guo; Zicheng Zuo; Yongjun Li; Zhiyu Jia; Huibiao Liu; Yuliang Li

doi:10.1038/s41467-018-03896-4

Anchoring zero valence single atoms of nickel and iron on graphdiyne for hydrogen evolution

Yurui Xue, Bolong Huang, Yuanping Yi, Yuan Guo, Zicheng Zuo, Yongjun Li, Zhiyu Jia, Huibiao Liu, Yuliang Li^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

847 Citations (Scopus)

Abstract

Electrocatalysis by atomic catalysts is a major focus of chemical and energy conversion effort. Although transition-metal-based bulk electrocatalysts for electrochemical application on energy conversion processes have been reported frequently, anchoring the stable transition-metal atoms (e.g. nickel and iron) still remains a practical challenge. Here we report a strategy for fabrication of ACs comprising only isolated nickel/iron atoms anchored on graphdiyne. Our findings identify the very narrow size distributions of both nickel (1.23 Å) and iron (1.02 Å), typical sizes of single-atom nickel and iron. The precision of this method motivates us to develop a general approach in the field of single-atom transition-metal catalysis. Such atomic catalysts have high catalytic activity and stability for hydrogen evolution reactions.

Original language	English
Article number	1460
Journal	Nature Communications
Volume	9
Issue number	1
DOIs	https://doi.org/10.1038/s41467-018-03896-4
Publication status	Published - 1 Dec 2018
Externally published	Yes

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title = "Anchoring zero valence single atoms of nickel and iron on graphdiyne for hydrogen evolution",

abstract = "Electrocatalysis by atomic catalysts is a major focus of chemical and energy conversion effort. Although transition-metal-based bulk electrocatalysts for electrochemical application on energy conversion processes have been reported frequently, anchoring the stable transition-metal atoms (e.g. nickel and iron) still remains a practical challenge. Here we report a strategy for fabrication of ACs comprising only isolated nickel/iron atoms anchored on graphdiyne. Our findings identify the very narrow size distributions of both nickel (1.23 {\AA}) and iron (1.02 {\AA}), typical sizes of single-atom nickel and iron. The precision of this method motivates us to develop a general approach in the field of single-atom transition-metal catalysis. Such atomic catalysts have high catalytic activity and stability for hydrogen evolution reactions.",

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T1 - Anchoring zero valence single atoms of nickel and iron on graphdiyne for hydrogen evolution

AU - Xue, Yurui

AU - Huang, Bolong

AU - Yi, Yuanping

AU - Guo, Yuan

AU - Zuo, Zicheng

AU - Li, Yongjun

AU - Jia, Zhiyu

AU - Liu, Huibiao

AU - Li, Yuliang

PY - 2018/12/1

Y1 - 2018/12/1

N2 - Electrocatalysis by atomic catalysts is a major focus of chemical and energy conversion effort. Although transition-metal-based bulk electrocatalysts for electrochemical application on energy conversion processes have been reported frequently, anchoring the stable transition-metal atoms (e.g. nickel and iron) still remains a practical challenge. Here we report a strategy for fabrication of ACs comprising only isolated nickel/iron atoms anchored on graphdiyne. Our findings identify the very narrow size distributions of both nickel (1.23 Å) and iron (1.02 Å), typical sizes of single-atom nickel and iron. The precision of this method motivates us to develop a general approach in the field of single-atom transition-metal catalysis. Such atomic catalysts have high catalytic activity and stability for hydrogen evolution reactions.

AB - Electrocatalysis by atomic catalysts is a major focus of chemical and energy conversion effort. Although transition-metal-based bulk electrocatalysts for electrochemical application on energy conversion processes have been reported frequently, anchoring the stable transition-metal atoms (e.g. nickel and iron) still remains a practical challenge. Here we report a strategy for fabrication of ACs comprising only isolated nickel/iron atoms anchored on graphdiyne. Our findings identify the very narrow size distributions of both nickel (1.23 Å) and iron (1.02 Å), typical sizes of single-atom nickel and iron. The precision of this method motivates us to develop a general approach in the field of single-atom transition-metal catalysis. Such atomic catalysts have high catalytic activity and stability for hydrogen evolution reactions.

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Anchoring zero valence single atoms of nickel and iron on graphdiyne for hydrogen evolution

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