The activation of bridged N atoms based on the structure engineering of PCN to boosts the release of visible-light photocatalytic hydrogen

Jin Zhang; Zengjian Liu; Yingfei Wan; Jie Zhang; Jinwei Chen; Gang Wang; Bingbing Chen; Ruilin Wang

doi:10.1016/j.cej.2022.135708

The activation of bridged N atoms based on the structure engineering of PCN to boosts the release of visible-light photocatalytic hydrogen

Jin Zhang, Zengjian Liu, Yingfei Wan, Jie Zhang, Jinwei Chen, Gang Wang, Bingbing Chen, Ruilin Wang

School of energy science and engineering

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

12 Scopus citations

Abstract

The inherent electronic structure of the bridged N atoms of polymeric carbon nitride (PCN) weakens the carriers transport process, which seriously reduced the activity of PCN. How to modulate the electronic structure of bridged N and break its limitation of charge transfer is a major challenge. Herein, PCN with bridged N atoms activated (PCNG) was designed and synthesized by the thermal copolymerization of glyoxal and melamine. Experimental and DFT calculation results show that the strong hydrogen evolution ability of PCNG is due to the wide visible absorption range, which is contributed by the mid-gap states. More importantly, the LUMO of PCNG shows great delocalization on the all-heptazine units and forms a polarized electric field between heptazine units. Therefore, the optimal PCNG-1 performs so far high H₂ evolution rate (261 umol·h⁻¹) and apparent quantum yield (AQY = 5.32%, λ = 420 nm), under the visible light.

Original language	English
Article number	135708
Journal	Chemical Engineering Journal
Volume	439
DOIs	https://doi.org/10.1016/j.cej.2022.135708
State	Published - 1 Jul 2022

Keywords

Activated bridged N atoms
First-principle calculations
Mid-gap states
Polarized electric field
Polymeric carbon nitride
Structural design

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10.1016/j.cej.2022.135708

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title = "The activation of bridged N atoms based on the structure engineering of PCN to boosts the release of visible-light photocatalytic hydrogen",

abstract = "The inherent electronic structure of the bridged N atoms of polymeric carbon nitride (PCN) weakens the carriers transport process, which seriously reduced the activity of PCN. How to modulate the electronic structure of bridged N and break its limitation of charge transfer is a major challenge. Herein, PCN with bridged N atoms activated (PCNG) was designed and synthesized by the thermal copolymerization of glyoxal and melamine. Experimental and DFT calculation results show that the strong hydrogen evolution ability of PCNG is due to the wide visible absorption range, which is contributed by the mid-gap states. More importantly, the LUMO of PCNG shows great delocalization on the all-heptazine units and forms a polarized electric field between heptazine units. Therefore, the optimal PCNG-1 performs so far high H2 evolution rate (261 umol·h−1) and apparent quantum yield (AQY = 5.32%, λ = 420 nm), under the visible light.",

keywords = "Activated bridged N atoms, First-principle calculations, Mid-gap states, Polarized electric field, Polymeric carbon nitride, Structural design",

author = "Jin Zhang and Zengjian Liu and Yingfei Wan and Jie Zhang and Jinwei Chen and Gang Wang and Bingbing Chen and Ruilin Wang",

note = "Publisher Copyright: {\textcopyright} 2022",

year = "2022",

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doi = "10.1016/j.cej.2022.135708",

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T1 - The activation of bridged N atoms based on the structure engineering of PCN to boosts the release of visible-light photocatalytic hydrogen

AU - Zhang, Jin

AU - Liu, Zengjian

AU - Wan, Yingfei

AU - Zhang, Jie

AU - Chen, Jinwei

AU - Wang, Gang

AU - Chen, Bingbing

AU - Wang, Ruilin

PY - 2022/7/1

Y1 - 2022/7/1

N2 - The inherent electronic structure of the bridged N atoms of polymeric carbon nitride (PCN) weakens the carriers transport process, which seriously reduced the activity of PCN. How to modulate the electronic structure of bridged N and break its limitation of charge transfer is a major challenge. Herein, PCN with bridged N atoms activated (PCNG) was designed and synthesized by the thermal copolymerization of glyoxal and melamine. Experimental and DFT calculation results show that the strong hydrogen evolution ability of PCNG is due to the wide visible absorption range, which is contributed by the mid-gap states. More importantly, the LUMO of PCNG shows great delocalization on the all-heptazine units and forms a polarized electric field between heptazine units. Therefore, the optimal PCNG-1 performs so far high H2 evolution rate (261 umol·h−1) and apparent quantum yield (AQY = 5.32%, λ = 420 nm), under the visible light.

AB - The inherent electronic structure of the bridged N atoms of polymeric carbon nitride (PCN) weakens the carriers transport process, which seriously reduced the activity of PCN. How to modulate the electronic structure of bridged N and break its limitation of charge transfer is a major challenge. Herein, PCN with bridged N atoms activated (PCNG) was designed and synthesized by the thermal copolymerization of glyoxal and melamine. Experimental and DFT calculation results show that the strong hydrogen evolution ability of PCNG is due to the wide visible absorption range, which is contributed by the mid-gap states. More importantly, the LUMO of PCNG shows great delocalization on the all-heptazine units and forms a polarized electric field between heptazine units. Therefore, the optimal PCNG-1 performs so far high H2 evolution rate (261 umol·h−1) and apparent quantum yield (AQY = 5.32%, λ = 420 nm), under the visible light.

KW - Activated bridged N atoms

KW - First-principle calculations

KW - Mid-gap states

KW - Polarized electric field

KW - Polymeric carbon nitride

KW - Structural design

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DO - 10.1016/j.cej.2022.135708

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JO - Chemical Engineering Journal

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The activation of bridged N atoms based on the structure engineering of PCN to boosts the release of visible-light photocatalytic hydrogen

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