Process optimization of plasma-catalytic formaldehyde removal using MnOx–Fe2O3 catalysts by response surface methodology

Process optimization of plasma-catalytic formaldehyde removal using MnOx–Fe2O3 catalysts by response surface methodology

To remove the toxic formaldehyde efficiently, a non-thermal plasma (NTP) system incorporated with MnOx–Fe2O3 catalyst has been developed herein. A response surface methodology (RSM) was utilized to explore the effects of a variety of experimental parameters (gas flow rate, molar ratio of Fe/Mn, and...

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Bibliographic Details
Published in:Journal of environmental chemical engineering Vol. 9; no. 4; p. 105773
Main Authors: Chang, Tian, Shen, Zhenxing, Ma, Chuanlong, Lu, Jiaqi, Huang, Yu, Veerapandian, Savita K.P., De Geyter, Nathalie, Morent, Rino
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-08-2021
Subjects:
Catalyst
Formaldehyde
Non-thermal plasma
Response surface methodology
Non-thermal plasma
Response surface methodology
Catalyst
Formaldehyde
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Summary:To remove the toxic formaldehyde efficiently, a non-thermal plasma (NTP) system incorporated with MnOx–Fe2O3 catalyst has been developed herein. A response surface methodology (RSM) was utilized to explore the effects of a variety of experimental parameters (gas flow rate, molar ratio of Fe/Mn, and discharge power) on formaldehyde degradation systematically. The results demonstrated that the discharge power has the greatest impact on the formaldehyde degradation process, while the molar ratio of Fe/Mn has the least influence. Moreover, the amount of adsorbed oxygen species, reducibility, and average specific surface area of the tested catalyst are estimated as the dominant factors influencing the catalytic performance. Importantly, the optimal formaldehyde removal efficiency (95.01%) and CO2 selectivity (86.20%) were acquired at 5 W discharge power, 0.5 L min−1 gas flow rate, and 0.71 Fe/Mn molar ratio. This study can thus provide an efficient strategy for formaldehyde removal. [Display omitted] •Efficient oxidation of formaldehyde to CO2 in the post-plasma-MnOx–Fe2O3 system.•Modeling and optimization of formaldehyde removal process in the PPC system.•Discharge power is the most significant factor affecting the HCHO degradation.•Optimum formaldehyde removal (95.01%) and CO2 selectivity (86.20%) were obtained.•Active oxygen specie is beneficial factor for formaldehyde oxidation.
ISSN:2213-3437
2213-3437
DOI:10.1016/j.jece.2021.105773