Journal
CHEMICAL ENGINEERING JOURNAL
Volume 442, Issue -, Pages -Publisher
ELSEVIER SCIENCE SA
DOI: 10.1016/j.cej.2022.136333
Keywords
Multicomponent catalyst; In-situ IR; Mechanism; Carbon radicals and intermediates; H-2 yield
Categories
Funding
- ERDF A way of making Europe [PID2019-105490RB-C31, MCIN/AEI/10.13039/501100011033]
- European Union
- EU FEDER
- Junta de Andalucia [P20-00156]
- ESF Investing in your future [BES-2017-080069]
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Optimization of Pt-promoted TiO2-based is crucial for enhancing photocatalytic production of hydrogen. Doping and surface decoration are exploited to maximize hydrogen yield. The composite system shows activity boost up to 7.3 times within the whole methanol:water mixture ratio, with quantum efficiencies in the range of approximately 13-16%. In-situ spectroscopic study examines the role of different components in generating charge carrier species and controlling reaction kinetics, revealing the complex reaction mechanism and physical origin of H2 production enhancement in doped-composite titania-based catalysts.
Optimization of Pt-promoted TiO2-based is key to promote the photocatalytic production of hydrogen using sacrificial alcohol molecules. Combination of doping and surface decoration of the mentioned base photoactive material is here exploited to maximize hydrogen yield. Using the quantum efficiency parameter, it is shown that the resulting composite system can boost activity up to 7.3 times within the whole methanol:water mixture ratio, yielding quantum efficiencies in the ca. 13-16 % range. The key role of the different components in generating charge carrier species and their use to trigger the sacrificial molecule evolution and control reaction kinetics are examined through an in-situ spectroscopic study. The study unveils the complex reaction mechanism, with generation of C1 to C3 molecules from different carbon-containing radicals, and interprets the physical origin of the huge H2 production enhancement occurring in doped-composite titania-based catalysts.
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