Bio-inspired multilayered graphene-directed assembly of monolithic photo-membrane for full-visible light response and efficient charge separation

Highly efficient and easily recyclable CdS/ZnO/rGO photomembrane with full-visible light response and efficient charge separation has achieved the excellent photocatalytic and photoelectrochemical hydrogen generations. [Display omitted] •CdS/ZnO nanocage arrays were synthesized on the interspaces of...

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Bibliographic Details
Published in:Applied catalysis. B, Environmental Environmental, 2020-04, Vol.263, p.117587, Article 117587
Main Authors: Zhong, Yongming, Yang, Siyuan, Cai, Xin, Zhang, Shengsen, Gao, Qiongzhi, Liu, Yingju, Yang, Zhuohong, Yang, Shihe, Fang, Yueping
Format: Article
Language:English
Subjects:
Arrays
Cadmium sulfide
Catalysts
Charge transport
Clean energy
Electromagnetic absorption
Full-visible light photocatalysis
Graphene
Graphene embedded nanowire array
Green hydrogen
Heterojunctions
Heterostructures
Hydrogen
Hydrogen fuels
Hydrogen generation
Hydrogen production
Infrared radiation
Interfaces
Irradiation
Light
Light irradiation
Membranes
Multilayers
Nanostructure
Performance enhancement
Photocatalysis
Photocatalysts
Photoelectric effect
Photoelectric emission
Photoelectrochemistry
Photomembrane
Separation
Solar energy
Zinc oxide
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Summary:Highly efficient and easily recyclable CdS/ZnO/rGO photomembrane with full-visible light response and efficient charge separation has achieved the excellent photocatalytic and photoelectrochemical hydrogen generations. [Display omitted] •CdS/ZnO nanocage arrays were synthesized on the interspaces of rGO membrane.•The photomembrane can be used as both photocatalyst or photo-electrode.•The effective light range were extend to near-infrared light (λ = 700 nm).•Photo-oxidation and -reduction were separated on macroscopic scale.•46.08 umol h−1 cm-2 H2 generation rate and 4.51% ABPE value were achieved. Highly efficient and easily recyclable monolithic photocatalysts with elaborate hierarchical heterostructure and functional components are desirable to tap solar energy and produce green hydrogen fuels for the sustainable future. Inspired by the natural leaves, here we have rationally designed and fabricated an efficient artificial leaf photocatalyst, i.e., the first monolithic photomembrane of CdS/ZnO nanocage arrays grown into the interspaces of multilayered reduced graphene oxide (rGO) nanosheets (denoted as CdS/ZnO/rGO). The CdS/ZnO/rGO have elaborate hierarchical porous heterostructure and multifunctional components, such as multilayer rGO nanosheets for visible light absorption/harvesting, rapid charge transport and collection, hollowed CdS/ZnO nanocage arrays for light harvesting and charge utilization, and multiple heterojunction interfaces for efficient charge separation. It can been used not only as a monolithic photocatalyst, but also directly as a freestanding photoanode in the photoelectrochemical (PEC) cell system, exhibits an enhanced performance of photocatalytic (PC) or PEC hydrogen generation under different monochrome light irradiation in full-visible light region. Moreover, the CdS/ZnO/rGO photo-membrane can macroscopically realize the separation of photogenerated hole elimination and hydrogen generation by adjusting co-catalysts loading position. Impressively, it still delivered a PC H2 generation activity (0.79 μmol cm−2  h-1) and a photocurrent response of 250 μA cm-2 even under near-infrared light (λ = 700 nm) irradiation, a striking feature rarely achieved in prior arts.
ISSN:0926-3373
1873-3883
DOI:10.1016/j.apcatb.2019.03.074