Inside Cover: Elucidating the Electrocatalytic CO 2  Reduction Reaction over a Model Single‐Atom Nickel Catalyst (Angew. Chem. Int. Ed. 2/2020) | Zendy

Liu Song | Zendy; Yang Hong Bin | Zendy; Hung SungFu | Zendy; Ding Jie | Zendy; Cai Weizheng | Zendy; Liu Linghui | Zendy; Gao Jiajian | Zendy; Li Xuning | Zendy; Ren Xinyi | Zendy; Kuang Zhichong | Zendy; Huang Yanqiang | Zendy; Zhang Tao | Zendy; Liu Bin | Zendy

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Inside Cover: Elucidating the Electrocatalytic CO 2 Reduction Reaction over a Model Single‐Atom Nickel Catalyst (Angew. Chem. Int. Ed. 2/2020)

Author(s) -

Liu Song,

Yang Hong Bin,

Hung SungFu,

Ding Jie,

Cai Weizheng,

Liu Linghui,

Gao Jiajian,

Li Xuning,

Ren Xinyi,

Kuang Zhichong,

Huang Yanqiang,

Zhang Tao,

Liu Bin

Publication year - 2020

Publication title -

angewandte chemie international edition

Language(s) - English

Resource type - Reports

SCImago Journal Rank - 5.831

H-Index - 550

eISSN - 1521-3773

pISSN - 1433-7851

DOI - 10.1002/anie.201915193

Subject(s) - nickel , catalysis , electrochemistry , faraday efficiency , covalent bond , carbon nanotube , cover (algebra) , atom (system on chip) , carbon fibers , materials science , chemistry , inorganic chemistry , nanotechnology , electrode , organic chemistry , composite material , composite number , computer science , engineering , embedded system , mechanical engineering

If I had a nickel ! A model nickel single‐atom catalyst bearing uniform and well‐defined Ni‐N 4 moieties was prepared by coordinating molecular nickel phthalocyanine to carbon nanotubes through C−C covalent bonds. In their Research Article on page 798, Y. Huang and B. Liu et al. describe a highly active catalyst for electrochemical CO 2 to CO reduction with a high Faradaic efficiency and turnover frequency. The active site is an in situ generated Ni + species.

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