Correlating the properties of hydrogenated titania to reaction kinetics and mechanism for the photocatalytic degradation of bisphenol A under solar irradiation

[Display omitted] •Properties of hydrogenated TiO2 depend on the annealing temperature at 400–800°C.•Thermal treatment under H2 promotes Na diffusion from catalyst bulk to the surface.•Volcano-type dependence of BPA degradation on annealing temperature (max at 600°C).•TiΟ2 and BPA concentration, ele...

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Published in:Applied catalysis. B, Environmental Environmental, 2016-07, Vol.188, p.65-76
Main Authors: Ioannidou, Evangelia, Ioannidi, Alexandra, Frontistis, Zacharias, Antonopoulou, Maria, Tselios, Charalampos, Tsikritzis, Dimitris, Konstantinou, Ioannis, Kennou, Stella, Kondarides, Dimitris I., Mantzavinos, Dionissios
Format: Article
Language:English
Subjects:
Activity
Annealing
Annealing temperature
Bisphenol A
Byproducts
Catalyst characterization
Catalysts
Degradation
Pathways
Photocatalysis
Roasting
Sodium
Titanium dioxide
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Summary:[Display omitted] •Properties of hydrogenated TiO2 depend on the annealing temperature at 400–800°C.•Thermal treatment under H2 promotes Na diffusion from catalyst bulk to the surface.•Volcano-type dependence of BPA degradation on annealing temperature (max at 600°C).•TiΟ2 and BPA concentration, electron acceptors and the water matrix affect kinetics.•Distribution of reaction by-products is affected by the type of catalyst used. Hydrogenation of a commercially available TiO2 anatase catalyst was carried out at several annealing temperatures in the range 400–800°C to improve its photocatalytic activity for the degradation of endocrine disruptor bisphenol A (BPA) under simulated solar irradiation. The prepared hydrogenated catalysts, as well as their counterparts calcined in air were characterized with respect to their morphological, optical and electronic properties by means of BET, XRD, XPS, DRS and UPS analyses. Thermal treatment under flowing hydrogen resulted in increased absorption at wavelengths below 400nm, as well as in the appearance of a broad and almost uniform absorption band in the visible region, the intensity of which increased with increase of annealing temperature. The latter was attributed to the creation of gap states in the hydrogenated samples, which was not observed for the samples calcined in air. Interestingly, sodium inherently present in the bulk of the pristine catalyst was found to diffuse at the surface and this was more pronounced for the hydrogenated samples prepared at temperatures above 700°C. The relative catalytic activity was tested to degrade 240μg/L BPA in pure water and it was found that the hydrogenated catalysts were more active than those calcined in air at the same temperatures. The maximum rate (0.0647min−1) was observed for the catalyst hydrogenated at 600°C, i.e. three times greater than the respective calcined catalyst. Higher annealing temperatures had a detrimental effect on photocatalytic activity and this may be associated with a collapse of the specific surface area. Other than the annealing temperature, the rate was also strongly dependent on the water matrix (slower for more complex matrices), BPA and catalyst concentration and the presence of electron acceptors. LC–MS/TOF analysis was employed to identify transformation by-products (TBPs) and elucidate reaction pathways. BPA degradation by hydrogenated catalysts seems to occur mainly through consecutive hydroxylation/oxidation reactions, as evidenced by
ISSN:0926-3373
1873-3883
DOI:10.1016/j.apcatb.2016.01.060