Carbon quantum dots enriching molecular nickel polyoxometalate over CdS semiconductor for photocatalytic water splitting

[Display omitted] •The Ni4P2-CQDs@CdS composite is designed for pure water splitting without addition sacrificial agents.•This is the first report of CQDs enriching Ni4P2 POM over CdS semiconductor for water splitting.•The photoinduced electrons in the CB of CdS migrate to CQDs, then to Ni4P2 for H2...

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Bibliographic Details
Published in:Applied catalysis. B, Environmental Environmental, 2021-09, Vol.293, p.120214, Article 120214
Main Authors: Dong, Yinjuan, Han, Qing, Hu, Qiyu, Xu, Chunjiang, Dong, Congzhao, Peng, Yong, Ding, Yong, Lan, Yaqian
Format: Article
Language:English
Subjects:
Cadmium sulfide
Carbon quantum dots
Catalysts
CdS
Electrons
Energy conversion
Enrichment effect
Evolution
Harvesters
Hydrogen evolution
Hydrogen peroxide
Irradiation
Light irradiation
Nickel
Photocatalysis
Photocatalysts
Photocatalytic water splitting
Polyoxometallate
Polyoxometallates
Quantum dots
Radiation
Reagents
Rotating disks
Solar energy
Solar energy conversion
Splitting
Water splitting
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Summary:[Display omitted] •The Ni4P2-CQDs@CdS composite is designed for pure water splitting without addition sacrificial agents.•This is the first report of CQDs enriching Ni4P2 POM over CdS semiconductor for water splitting.•The photoinduced electrons in the CB of CdS migrate to CQDs, then to Ni4P2 for H2 evolution.•The generated holes at the VB of CdS transfer to CQDs and oxidize H2O to H2O2. An efficient and stable photocatalyst for overall water splitting is desirable for solar-energy conversion. Herein, Ni4P2-CQDs@CdS catalyst was obtained in situ photoreaction CQDs@CdS semiconductor composite and [Ni4(H2O)2(PW9O34)2]10− (Ni4P2) polyoxometallate. Photocatalytic hydrogen evolution from pure water is realized using CdS as the light harvester, CQDs as the electron acceptor and donor and Ni4P2 as catalyst without addition sacrificial reagents under visible light irradiation (λ = 420 nm), which exhibits water splitting activity with H2 evolution rate up to 145 μmol gcat-1 h-1. Experiments confirm the electrons transfer from CdS to CQDs, then to Ni4P2, resulting in accumulation of the electrons in Ni4P2 for H2 evolution. The generated holes at the VB of CdS transfer to CQDs and oxidize H2O to H2O2. The rotating ring-disk electrode test confirms the two-electron process (2H2O → H2 + H2O2). This work proposes an elegant strategy for how to design multicomponent photocatalyst to realize efficient water splitting.
ISSN:0926-3373
1873-3883
DOI:10.1016/j.apcatb.2021.120214