Yolk-shell ZnO@C-CeO2 ternary heterostructures with conductive N-doped carbon mediated electron transfer for highly efficient water splitting

[Display omitted] •A facile synthesis route is utilized to produce Z-scheme yolk-shell ZnO@C-CeO2.•After calcination, a conductive N-doped graphitic carbon layer is generated.•The photocatalysts showed enhancement toward visible light absorption.•A superior PEC water splitting performance is achieve...

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Bibliographic Details
Published in:Journal of colloid and interface science 2022-01, Vol.605, p.23-32
Main Authors: Celebi, Nuray, Salimi, Kouroush
Format: Article
Language:English
Subjects:
CeO2
Hydrogen generation
N-doped graphitic carbon
Photocatalysis
ZnO
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Summary:[Display omitted] •A facile synthesis route is utilized to produce Z-scheme yolk-shell ZnO@C-CeO2.•After calcination, a conductive N-doped graphitic carbon layer is generated.•The photocatalysts showed enhancement toward visible light absorption.•A superior PEC water splitting performance is achieved: 7.43 mA/cm2 at 1.18 V RHE.•N-doped carbon electron-transfer layer prolonged life-time of light in yolk-shell. Herein, carbon-incorporated yolk-shell ZnO@C-CeO2 ternary heterostructures are employed as visible light responsive photocatalyst for highly efficient photoelectrochemical (PEC) water splitting. Compared to conventional ZnO/CeO2 semiconductors, introduction of a thin PDA shell layer assures the generation of a conductive N-doped graphitic carbon layer after a calcination post-treatment with mesoporous hollow morphologies. The evaluation of PEC water splitting performance of ZnO@C-CeO2 photoanodes reveals the maximum photocurrent density as 7.43 mA/cm2 at 1.18 V RHE under light whereas almost no response is recorded at dark. These superior PEC H2 evolution performance strongly implies efficient charge separation, facilitated charge transfer between photoanode and electrolyte interface as well as within the semiconductor bulk by means of rapid electron transfer ability of N-doped graphitic carbon layer and prolong life time of light inside yolk-shell structure. Furthermore, considerable depression in PL intensity of ZnO@C-CeO2 photoanodes compared to ZnO clearly reveals a higher photon absorption due to the reflection of light in hollow region and increase in electron hole separation efficiency. Moreover, plausible Z-scheme charge transfer mechanism using ZnO@C-CeO2 photoanodes under visible light illumination is verified using radical trapping experiments and X-ray photoelectron spectroscopy (XPS) methods, suggesting new generation of heterostructures for sufficient conversion of sunlight to H2 fuels.
ISSN:0021-9797
1095-7103
DOI:10.1016/j.jcis.2021.07.052