Unravelling the photoactivity of metal-loaded TiO2 for hydrogen production: insights from a combined experimental and computational analysis
Unravelling the photoactivity of metal-loaded TiO2 for hydrogen production: insights from a combined experimental and computational analysis
Despite being the most employed material for photocatalytic hydrogen generation, TiO2 suffers limitations such as a high rate of electron-hole recombination and poor light absorption in the visible spectrum. Among the various strategies developed to overcome these drawbacks, combining TiO2 with a metal co-catalyst emerged as one of the most promising. In this study, we integrated experimental findings, advanced characterization techniques, and computational methods to shed light on how different noble metals influence the enhancement of the photocatalytic activity of TiO2. Among the tested noble metal co-catalysts, the hydrogen production rate under UV and visible light irradiation followed the trend Pt > Au ≈ Pd > Ag > bare TiO2, with Pt-decorated TiO2 exhibiting a hydrogen production rate of 28 mmol/h g. The noble metals were found to significantly suppress the electron-hole recombination rate compared to bare TiO2. Upon photodeposition, Pd and Pt formed the smallest nanoparticles with average sizes of 13.4 nm and 4.1 nm, respectively. Computational analyses were conducted to rationalize the difference in nanoparticle sizes by analyzing the binding and cohesive energies of the metal clusters on the TiO2 surface. Additionally, calculations demonstrated the strong interaction of Pt, Au, and Pd nanoclusters with adsorbed hydrogen, with Pt achieving the closest-to-zero Gibbs free energy of hydrogen adsorption and displaying the most polar interaction with hydrogen. These findings align closely with the observed hydrogen production rates, where UV/Vis-driven hydrogen production is governed by the coupling of hydrogen radicals on the co-catalyst surface, while visible-light-driven production is limited by charge carrier lifetimes.
394-406
Hamdan, Sarah
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Wigglesworth, Matthew J.
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Muscetta, Marica
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Ma, Ruiman
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Helal, Mohamed I.
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Martsinovich, Natalia
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Palmisano, Giovanni
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Vernuccio, Sergio
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19 March 2025
Hamdan, Sarah
b7501f82-1fc5-4cd6-9456-4951a3b5bc1b
Wigglesworth, Matthew J.
370f7502-ecac-4814-8f0e-19240b99b363
Muscetta, Marica
7bbcc385-fb8e-4616-80dd-2703e87b031d
Ma, Ruiman
cc820a40-3ec3-40e9-bf60-9d2b969bfa9a
Helal, Mohamed I.
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Martsinovich, Natalia
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Palmisano, Giovanni
8046c985-76d4-4c87-b628-d5328b1f2038
Vernuccio, Sergio
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Hamdan, Sarah, Wigglesworth, Matthew J., Muscetta, Marica, Ma, Ruiman, Helal, Mohamed I., Martsinovich, Natalia, Palmisano, Giovanni and Vernuccio, Sergio
(2025)
Unravelling the photoactivity of metal-loaded TiO2 for hydrogen production: insights from a combined experimental and computational analysis.
International Journal of Hydrogen Energy, 118, .
(doi:10.1016/j.ijhydene.2025.03.184).
Abstract
Despite being the most employed material for photocatalytic hydrogen generation, TiO2 suffers limitations such as a high rate of electron-hole recombination and poor light absorption in the visible spectrum. Among the various strategies developed to overcome these drawbacks, combining TiO2 with a metal co-catalyst emerged as one of the most promising. In this study, we integrated experimental findings, advanced characterization techniques, and computational methods to shed light on how different noble metals influence the enhancement of the photocatalytic activity of TiO2. Among the tested noble metal co-catalysts, the hydrogen production rate under UV and visible light irradiation followed the trend Pt > Au ≈ Pd > Ag > bare TiO2, with Pt-decorated TiO2 exhibiting a hydrogen production rate of 28 mmol/h g. The noble metals were found to significantly suppress the electron-hole recombination rate compared to bare TiO2. Upon photodeposition, Pd and Pt formed the smallest nanoparticles with average sizes of 13.4 nm and 4.1 nm, respectively. Computational analyses were conducted to rationalize the difference in nanoparticle sizes by analyzing the binding and cohesive energies of the metal clusters on the TiO2 surface. Additionally, calculations demonstrated the strong interaction of Pt, Au, and Pd nanoclusters with adsorbed hydrogen, with Pt achieving the closest-to-zero Gibbs free energy of hydrogen adsorption and displaying the most polar interaction with hydrogen. These findings align closely with the observed hydrogen production rates, where UV/Vis-driven hydrogen production is governed by the coupling of hydrogen radicals on the co-catalyst surface, while visible-light-driven production is limited by charge carrier lifetimes.
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Accepted/In Press date: 11 March 2025
e-pub ahead of print date: 19 March 2025
Published date: 19 March 2025
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Local EPrints ID: 500572
URI: http://eprints.soton.ac.uk/id/eprint/500572
ISSN: 0360-3199
PURE UUID: 2e4cfc31-46bb-4eb9-a524-e95f2d049475
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Date deposited: 06 May 2025 16:47
Last modified: 22 Aug 2025 02:46
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Contributors
Author:
Sarah Hamdan
Author:
Matthew J. Wigglesworth
Author:
Marica Muscetta
Author:
Ruiman Ma
Author:
Mohamed I. Helal
Author:
Natalia Martsinovich
Author:
Giovanni Palmisano
Author:
Sergio Vernuccio
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