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

942 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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