Abstract
TiO2 prepared by a green aqueous sol–gel peptization process is co-doped with nitrogen and zirconium to improve and extend its photoactivity to the visible region. Two nitrogen precursors are used: urea and triethylamine; zirconium (IV) tert-butoxide is added as a source of zirconia. The N/Ti molar ratio is fixed regardless of the chosen nitrogen precursor while the quantity of zirconia is set to 0.7, 1.4, 2, or 2.8 mol%. The performance and physico-chemical properties of these materials are compared with the commercial Evonik P25 photocatalyst. For all doped and co-doped samples, TiO2 nanoparticles of 4 to 8 nm of size are formed of anatase-brookite phases, with a specific surface area between 125 and 280 m2 g−1 vs. 50 m2 g−1 for the commercial P25 photocatalyst. X-ray photoelectron (XPS) measurements show that nitrogen is incorporated into the TiO2 materials through Ti-O-N bonds allowing light absorption in the visible region. The XPS spectra of the Zr-(co)doped powders show the presence of TiO2-ZrO2 mixed oxide materials. Under visible light, the best co-doped sample gives a degradation of p-nitrophenol (PNP) equal to 70% instead of 25% with pure TiO2 and 10% with P25 under the same conditions. Similarly, the photocatalytic activity improved under UV/visible reaching 95% with the best sample compared to 50% with pure TiO2. This study suggests that N/Zr co-doped TiO2 nanoparticles can be produced in a safe and energy-efficient way while being markedly more active than state-of-the-art photocatalytic materials under visible light.
Highlights
Industrial development is the main cause of the increase of pollution in water [1]. these polluted effluents undergo various physical, chemical, and biological treatments [2], some pollutants are not degraded and return to the ecosystem [3].Advanced oxidation processes (AOPs) are among the most efficient processes for the total mineralization of organic compounds [4,5,6]
Concerning the notation of samples used in this study, samples doped with urea are designated TiO2 /Ux, where x is the molar ratio between titanium dioxide and urea
Samples doped with triethylamine are designated TiO2 /Ny, where y is the molar ratio between titanium dioxide and triethylamine
Summary
Industrial development is the main cause of the increase of pollution in water [1]. these polluted effluents undergo various physical, chemical, and biological treatments [2], some pollutants are not degraded and return to the ecosystem [3].Advanced oxidation processes (AOPs) are among the most efficient processes for the total mineralization of organic compounds [4,5,6]. Industrial development is the main cause of the increase of pollution in water [1] These polluted effluents undergo various physical, chemical, and biological treatments [2], some pollutants are not degraded and return to the ecosystem [3]. Photons with sufficient photon energy can promote an electron from the semiconductor’s valence band to its conduction band These photogenerated species migrate at the surface of the photocatalysts and can do redox reactions with the surrounding medium. In water, this leads to the production of hydroxyl radicals ·OH, the most powerful oxidizing species, and the formation of the superoxide radical O2− ·
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