http://www.cnr.it/ontology/cnr/individuo/prodotto/ID267374

Low irradiance photocatalytic degradation of toluene in air by screen-printed titanium dioxide layers (Articolo in rivista)

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Low irradiance photocatalytic degradation of toluene in air by screen-printed titanium dioxide layers (Articolo in rivista) (literal)

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Alberto Strini (a), Alessandra Sanson (b), Elisa Mercadelli (b), Alex Sangiorgi (b), Luca Schiavi (a) (2013)
Low irradiance photocatalytic degradation of toluene in air by screen-printed titanium dioxide layers
in Thin solid films (Print); ELSEVIER SCIENCE SA LAUSANNE, PO BOX 564, 1001 LAUSANNE 1 (Svizzera)
(literal)

Http://www.cnr.it/ontology/cnr/pubblicazioni.owl#autori

Alberto Strini (a), Alessandra Sanson (b), Elisa Mercadelli (b), Alex Sangiorgi (b), Luca Schiavi (a) (literal)

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Titolo

Low irradiance photocatalytic degradation of toluene in air by screen-printed titanium dioxide layers (literal)

Abstract

Screen-printed titania photocatalytic layers made from Degussa P25 were studied in order to assess the potential of this deposition technology for the production of catalytic surfaces for airborne pollutant degradation. The deposited catalytic TiO2 layers were characterized by a low density (about 25% of the titania bulk crystal) typical of very porous films. The study was carried out using toluene at low concentration (12 ppb) as model pollutant and with a low UV-A irradiance level on the sample surface (200 µW cm-2). The catalyst layers were deposited on alumina and quartz substrates demonstrating a good catalytic depollution activity. The relationship between the layer thickness and the catalytic activity was studied in the 1 to 6.8 µm range indicating an optimal 3-4 µm film thickness. Thicker layers do not show significant increases in the catalytic activity. The optical transmittance was studied using quartz substrate samples, showing a severely reduced photon flux for layers deeper than 5 µm. The effect of post-printing thermal treatment was studied in the 500-900 °C range, demonstrating good catalytic activity for processing temperatures <= 700 °C. These results indicate that the screen-printing process can be a promising technology for the realization of high efficiency photocatalytic materials for air depollution applications at low UV-A irradiance. (literal)

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