Abatement of ammonia and butyraldehyde under non-thermal plasma and photocatalysis: Oxidation processes for the removal of mixture pollutants at pilot scale

[Display omitted] •Simultaneous degradation of butyraldehyde and ammonia is performed.•Synergistic effects of plasma-photocatalysis is observed to mineralize pollutants.•Impact of relative humidity on pollutant and ozone degradation is studied.•High CO2 selectivity and a remarkable decrease of ozone...

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Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2018-07, Vol.344, p.165-172
Main Authors: Abou Saoud, Wala, Assadi, Aymen Amine, Guiza, Monia, Bouzaza, Abdelkrim, Aboussaoud, Wael, Soutrel, Isabelle, Ouederni, Abdelmottaleb, Wolbert, Dominique, Rtimi, Sami
Format: Article
Language:English
Subjects:
Chemical engineering
Chemical Sciences
DBD-plasma
Environmental Engineering
Environmental Sciences
Mixture effect
Odorous pollutants
Photocatalysis
Synergetic effect
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Summary:[Display omitted] •Simultaneous degradation of butyraldehyde and ammonia is performed.•Synergistic effects of plasma-photocatalysis is observed to mineralize pollutants.•Impact of relative humidity on pollutant and ozone degradation is studied.•High CO2 selectivity and a remarkable decrease of ozone concentration were observed.•Degradation by-products of C4H8O/NH3 were identified during plasma-photocatalysis. Dielectric barrier discharge DBD-plasma based technologies have been widely investigated for the abatement of air pollutants. More recently, photocatalysis (TiO2/UV-lamp) has also showed promising results for air pollution abatement. In this work, these two methods were used separately and combined (TiO2/UV-lamp/DBD-plasma) in order to enhance the performance of the process for air pollutants degradation/mineralization. Ammonia (NH3) and butyraldehyde (C4H8O) have been firstly treated alone and then an equimolar mixture (NH3/C4H8O) was monitored in a continuous reactor. Effect of operational parameters such as pollutants inlet concentration, flowrate, humidity and specific energy of plasma were thoroughly determined. Results showed that coupling both methods in the same reactor improves removal efficiency for single pollutant or a mixture of two pollutants. This processes combination showed a synergy between DBD-plasma and photocatalytic oxidation. Moreover, pollutant mineralization and potential intermediate byproducts have been characterized and discussed. Coupling both processes contributes to enhanced mineralization in comparison with DBD-plasma alone regarding the CO2 selectivity. As for selectivity of byproducts: (i) Relative Humidity (RH), (ii) mixture effect and (iii) (TiO2/UV-lamp/DBD-plasma) combined processes inhibit ozone production during the pollutants removal/oxidation.
ISSN:1385-8947
1873-3212
DOI:10.1016/j.cej.2018.03.068