Electron Configuration Modulation of Nickel Single Atoms for Elevated Photocatalytic Hydrogen Evolution

Xixiong Jin; Rongyan Wang; Lingxia Zhang; Rui Si; Meng Shen; Min Wang; Jianjian Tian; Jianlin Shi

doi:10.1002/anie.201914565

Electron Configuration Modulation of Nickel Single Atoms for Elevated Photocatalytic Hydrogen Evolution

Xixiong Jin, Rongyan Wang, Lingxia Zhang, Rui Si, Meng Shen, Min Wang, Jianjian Tian, Jianlin Shi

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

207 Scopus citations

Abstract

The emerging metal single-atom catalyst has aroused extensive attention in multiple fields, such as clean energy, environmental protection, and biomedicine. Unfortunately, though it has been shown to be highly active, the origins of the activity of the single-atom sites remain unrevealed to date owing to the lack of deep insight on electronic level. Now, partially oxidized Ni single-atom sites were constructed in polymeric carbon nitride (CN), which elevates the photocatalytic performance by over 30-fold. The 3d orbital of the partially oxidized Ni single-atom sites is filled with unpaired d-electrons, which are ready to be excited under irradiation. Such an electron configuration results in elevated light response, conductivity, charge separation, and mobility of the photocatalyst concurrently, thus largely augmenting the photocatalytic performance.

Original language	English
Pages (from-to)	6827-6831
Number of pages	5
Journal	Angewandte Chemie - International Edition
Volume	59
Issue number	17
DOIs	https://doi.org/10.1002/anie.201914565
State	Published - 20 Apr 2020
Externally published	Yes

Keywords

electronic modulation
photocatalysis
polymeric carbon nitride
single-atom catalysts
transition metals

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10.1002/anie.201914565

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abstract = "The emerging metal single-atom catalyst has aroused extensive attention in multiple fields, such as clean energy, environmental protection, and biomedicine. Unfortunately, though it has been shown to be highly active, the origins of the activity of the single-atom sites remain unrevealed to date owing to the lack of deep insight on electronic level. Now, partially oxidized Ni single-atom sites were constructed in polymeric carbon nitride (CN), which elevates the photocatalytic performance by over 30-fold. The 3d orbital of the partially oxidized Ni single-atom sites is filled with unpaired d-electrons, which are ready to be excited under irradiation. Such an electron configuration results in elevated light response, conductivity, charge separation, and mobility of the photocatalyst concurrently, thus largely augmenting the photocatalytic performance.",

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T1 - Electron Configuration Modulation of Nickel Single Atoms for Elevated Photocatalytic Hydrogen Evolution

AU - Jin, Xixiong

AU - Wang, Rongyan

AU - Zhang, Lingxia

AU - Si, Rui

AU - Shen, Meng

AU - Wang, Min

AU - Tian, Jianjian

AU - Shi, Jianlin

PY - 2020/4/20

Y1 - 2020/4/20

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AB - The emerging metal single-atom catalyst has aroused extensive attention in multiple fields, such as clean energy, environmental protection, and biomedicine. Unfortunately, though it has been shown to be highly active, the origins of the activity of the single-atom sites remain unrevealed to date owing to the lack of deep insight on electronic level. Now, partially oxidized Ni single-atom sites were constructed in polymeric carbon nitride (CN), which elevates the photocatalytic performance by over 30-fold. The 3d orbital of the partially oxidized Ni single-atom sites is filled with unpaired d-electrons, which are ready to be excited under irradiation. Such an electron configuration results in elevated light response, conductivity, charge separation, and mobility of the photocatalyst concurrently, thus largely augmenting the photocatalytic performance.

KW - electronic modulation

KW - photocatalysis

KW - polymeric carbon nitride

KW - single-atom catalysts

KW - transition metals

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Electron Configuration Modulation of Nickel Single Atoms for Elevated Photocatalytic Hydrogen Evolution

Abstract

Keywords

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