Synergistic enhancement of photocatalytic hydrogen production in TiO 2 nanosheets through light-induced defect formation and Pt single atoms

In this investigation, we present a direct method employing UV-light radiation to induce point defects, specifically Ti 3+ and V O , onto the surface of TiO 2 nanosheets (TiO 2 -NSs) and efficiently decorate them with Pt particles. The addition of the Pt precursor is carried out during rest periods...

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Published in:Journal of materials chemistry. A, Materials for energy and sustainability Materials for energy and sustainability, 2024-07, Vol.12 (29), p.18554-18562
Main Authors: Shahsanaei, Majid, Farahbakhsh, Nastaran, Pour-Ali, Sadegh, Schardt, Annika, Orangpour, Setareh, Engelhard, Carsten, Mohajernia, Shiva, Killian, Manuela S., Hejazi, Sina
Format: Article
Language:English
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Summary:In this investigation, we present a direct method employing UV-light radiation to induce point defects, specifically Ti 3+ and V O , onto the surface of TiO 2 nanosheets (TiO 2 -NSs) and efficiently decorate them with Pt particles. The addition of the Pt precursor is carried out during rest periods following UV-light cessation (light-induced samples, LI) and during UV-light exposure (photo-deposited samples, PD). The size and distribution of Pt particles on both LI and PD TiO 2 -NSs are systematically correlated with varying resting times, enabling precise control over Pt loading. The characterization of various TiO 2 -NSs is extensively conducted using microscopy techniques (FESEM, TEM, and HAADF-STEM) and spectroscopy (XPS). Gas chromatography is also employed for the evaluation of the H 2 photocatalytic performance of various samples. Our findings reveal that Pt particles deposit on the TiO 2 -NSs surfaces as nanoparticles under illumination. After a 5 minutes resting time, a combination of Pt single atoms (SAs) and clusters, with a maximum loading of 0.37 at%, is formed. Extending the resting time to 60 minutes results in a gradual reduction in Pt SAs and clusters, leading to the deposition of Pt nanoparticles with lower loadings. Notably, Pt SAs and clusters exhibit superior performance in hydrogen evolution, showcasing a remarkable 4000-fold increase over pristine TiO 2 -NSs. Additionally, sustained UV radiation during Pt addition in the photo-deposited samples results in the formation of Pt nanoparticles with lower loading compared to LI samples, consequently diminishing photocatalytic hydrogen production. This study not only provides insights into the controlled manipulation of Pt SAs on TiO 2 -NSs but also highlights their exceptional efficacy in hydrogen evolution, offering valuable contributions to the design of efficient photocatalytic systems for sustainable hydrogen generation.
ISSN:2050-7488
2050-7496
DOI:10.1039/D4TA01809E