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Robust S-scheme ZnO-TiO2-Ag with efficient charge separations for highly active hydrogen evolution performance and photocatalytic mechanism insight

Robust S-scheme ZnO-TiO2-Ag with efficient charge separations for highly active hydrogen evolution performance and photocatalytic mechanism insight
Robust S-scheme ZnO-TiO2-Ag with efficient charge separations for highly active hydrogen evolution performance and photocatalytic mechanism insight
The design and fabrication of photocatalysts for robust H2 evolution from photocatalytic water splitting has emerged as a hotspot in the domain of photocatalysis. Therefore, we have designed an S-scheme ZnO-TiO2-Ag (Zn-Ti-Ag) catalyst through the hydrothermal process to investigate photocatalytic H2 production under simulated sunlight exposure. The H2 production efficiency of Zn-Ti-Ag catalyst from water/formic acid solution is 60.4 mmolh−1g−1, which is exceptionally greater than that of pure ZnO (0.39 mmolh−1g−1) under identical experimental conditions. After five successive cycles, no obvious decline of photocatalytic activity over Zn-Ti-Ag verifies its outstanding stability for large-scale application. The exceptionally enhanced photocatalytic performance of Zn-Ti-Ag heterojunction can be attributed to efficient photocarriers separation and transport efficiency, improved light absorption resulting from the LSPR effect of Ag, and powerful redox potentials due to the construction of S-scheme. This research provides an efficient orientation to understand and design LSPR phenomenon-assisted oxides-based S-scheme heterojunctions for diverse photocatalytic applications.
H2 evolution, LSPR effect, S-scheme, TiO2, ZnO, simulated sunlight, H evolution, Simulated sunlight, TiO
0926-860X
Ahmad, Irshad
17cd7ea3-db73-4911-9bd0-a68d4874ad1f
Shukrullah, Shazia
6d2cd4c8-1242-468d-af54-a3fdd53c10db
Hussain, Humaira
d42be447-d14a-41eb-afb9-a71a6670e562
Yasin Naz, Muhammad
db9dc587-295a-468b-a229-a9646fa158ce
Khalid Alsaif, Faisaf
a3ad8382-a30d-426d-aa6b-11d17007a111
Alsulamy, Sager
a493454f-6a82-4990-943f-8ad11533f820
Khan, Yasin
14a4ef99-0347-45fe-becc-120a305e1da7
Ahmad, Irshad
17cd7ea3-db73-4911-9bd0-a68d4874ad1f
Shukrullah, Shazia
6d2cd4c8-1242-468d-af54-a3fdd53c10db
Hussain, Humaira
d42be447-d14a-41eb-afb9-a71a6670e562
Yasin Naz, Muhammad
db9dc587-295a-468b-a229-a9646fa158ce
Khalid Alsaif, Faisaf
a3ad8382-a30d-426d-aa6b-11d17007a111
Alsulamy, Sager
a493454f-6a82-4990-943f-8ad11533f820
Khan, Yasin
14a4ef99-0347-45fe-becc-120a305e1da7

Ahmad, Irshad, Shukrullah, Shazia, Hussain, Humaira, Yasin Naz, Muhammad, Khalid Alsaif, Faisaf, Alsulamy, Sager and Khan, Yasin (2023) Robust S-scheme ZnO-TiO2-Ag with efficient charge separations for highly active hydrogen evolution performance and photocatalytic mechanism insight. Applied Catalysis A: General, 662, [119259]. (doi:10.1016/j.apcata.2023.119259).

Record type: Article

Abstract

The design and fabrication of photocatalysts for robust H2 evolution from photocatalytic water splitting has emerged as a hotspot in the domain of photocatalysis. Therefore, we have designed an S-scheme ZnO-TiO2-Ag (Zn-Ti-Ag) catalyst through the hydrothermal process to investigate photocatalytic H2 production under simulated sunlight exposure. The H2 production efficiency of Zn-Ti-Ag catalyst from water/formic acid solution is 60.4 mmolh−1g−1, which is exceptionally greater than that of pure ZnO (0.39 mmolh−1g−1) under identical experimental conditions. After five successive cycles, no obvious decline of photocatalytic activity over Zn-Ti-Ag verifies its outstanding stability for large-scale application. The exceptionally enhanced photocatalytic performance of Zn-Ti-Ag heterojunction can be attributed to efficient photocarriers separation and transport efficiency, improved light absorption resulting from the LSPR effect of Ag, and powerful redox potentials due to the construction of S-scheme. This research provides an efficient orientation to understand and design LSPR phenomenon-assisted oxides-based S-scheme heterojunctions for diverse photocatalytic applications.

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More information

Accepted/In Press date: 7 May 2023
e-pub ahead of print date: 12 May 2023
Published date: 22 May 2023
Additional Information: Funding Information: This work was supported by the Researchers Supporting Project number ( RSPD2023R646 ), King Saud University , Riyadh, Saudi Arabia.
Keywords: H2 evolution, LSPR effect, S-scheme, TiO2, ZnO, simulated sunlight, H evolution, Simulated sunlight, TiO

Identifiers

Local EPrints ID: 483760
URI: http://eprints.soton.ac.uk/id/eprint/483760
DOI: doi:10.1016/j.apcata.2023.119259
ISSN: 0926-860X
PURE UUID: ae52ee57-e261-4d7e-be73-64d6caf44d3e

Catalogue record

Date deposited: 03 Nov 2023 20:17
Last modified: 17 Mar 2024 05:05

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Contributors

Author: Irshad Ahmad
Author: Shazia Shukrullah
Author: Humaira Hussain
Author: Muhammad Yasin Naz
Author: Faisaf Khalid Alsaif
Author: Sager Alsulamy
Author: Yasin Khan

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