Abstract
This work presents a comparative study of the efficiency of two commercial TiO2 photocatalysts, Aeroxide P25 (ATiO2) and Sachtleben Hombikat UV100 (HTiO2), in H2 production from an aqueous solution of naphthalene. The TiO2 photocatalysts were platinized by the photodeposition method varying the platinum content of the suspension to 0.5, 1.0, and 5.0 wt%. A full physicochemical characterization for these materials was performed, showing no structural effects from the deposition method, and confirming a well dispersion of nanosized-Pt0 particles on the surface of both photocatalysts. Pristine ATiO2 shows around 14% higher photocatalytic fractional conversion of naphthalene than pristine HTiO2 after 240 min of irradiation, while both materials exhibit negligible activity for H2 formation. The 0.5 wt% Pt- HTiO2 increases the photocatalytic fractional conversion of naphthalene from 71% to 82% and produces 6 µmol of H2. However, using a higher Pt content than the optimal platinization ratio of 0.5 wt% dramatically inhibits both processes. On the other hand, regardless of the fractional ratio of Pt, the platinization of ATiO2 results in a decrease in the fractional conversion of naphthalene by 4% to 33% of the pristine value. Although the presence of Pt islands on the surface of the ATiO2 is essential for the H2 evolution, no dependency between the Pt ratio and the H2 formation rate was observed since all the platinized materials show a similar H2 formation of around 3 µmol. Based on the EPR results, the higher photocatalytic activity of the Pt-HTiO2 is attributed to the efficient charge carrier separation and its larger surface area. The recyclability test confirms that the inhibition of the photocatalytic process is related to the deactivation of the photocatalyst surface by the adsorption of the photoformed intermediates. A strong relationship between the photocatalytic activity and the kind of the aromatic compounds was observed. The H2 evolution and the photooxidation of the aromatic hydrocarbons exhibit higher photonic efficiencies than that of their corresponding hydroxylated compounds over the Pt-HTiO2.
Highlights
Achieving a fully sustainable energy system for the future involves the development of multiple and diverse technologies
Pt-HTiO2 produces a relatively higher intense signal of such organic radicals and a stronger signal of the trapped electrons (Ti+3) compared to both signals produced from Pt-ATiO2. This could be attributed to the higher amount of the tapped holes that are available to react with the adsorb naphthalene, due to the efficient charge carrier separation in the Pt-HTiO2 photocatalyst
The presented results show that Pt-HTiO2 exhibits a higher photocatalytic activity for H2 evolution than Pt-ATiO2 during the photoreforming of the naphthalene
Summary
Achieving a fully sustainable energy system for the future involves the development of multiple and diverse technologies One of these systems is the renewable energy carriers, such as molecular hydrogen (H2), which possesses advantageous properties compared to petroleum and other fossil-derived fuels [1]. The development of methods for the conversion of these pollutants into chemical energy in the form of molecular hydrogen is a more attractive solution. Solar photocatalytic reforming of organic pollutants contained in wastewaters under anaerobic conditions may be a viable alternative to other renewable hydrogen technologies. These TiO2 photocatalysts were platinized using a photodeposition method by varying the platinum content of the suspension The difference in their activities was evaluated through the study of the charge carrier separation, H2 production, and naphthalene conversion during the photocatalytic process. The effect of the intermediate products during the photocatalytic process was investigated
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