Abstract: The paper is devoted to the oxidation of acetone and ethanol vapors by means of an optimized negative atmospheric corona discharge combined with TiO2-based catalysts located in a post-plasma position. A series of studied samples includes CuO-MnO2/TiO2, CuO/TiO2 and MnO2/TiO2 with 3 wt% of copper oxide and 6.8 wt% of manganese oxide. Experiments were performed at room temperature in a closed 404-L chamber with a ∼0.9-L active plasma region. It was shown that the use of the catalysts can provide a significant reduction in the concentrations of ozone and oxidation byproducts and a three-fold increased conversion of the reactants. It was unexpectedly found that copper oxide, as an active agent, did not significantly change the effect of post-plasma-located TiO2. The manganese-containing sample was found to be the best catalyst at the conditions considered. The presence of this catalyst in the post-plasma position inhibits the formation of unwanted products (O3 and CO) and promotes the deep oxidation of acetone and ethanol with increased selectivity toward CO2.

Cite: Lyulyukin M.N. , Besov A.S. , Vorontsov A.V.
Acetone and Ethanol Vapor Oxidation via Negative Atmospheric Corona Discharge over Titania-Based Catalysts
Applied Catalysis B: Environmental. 2016. V.183. P.18-27. DOI: 10.1016/j.apcatb.2015.10.025 WOS Scopus РИНЦ ANCAN OpenAlex

Dates:

Submitted:	Jul 6, 2015
Accepted:	Oct 12, 2015
Published online:	Oct 23, 2015
Published print:	Apr 1, 2016

Identifiers:

Web of science:	WOS:000367106200003
Scopus:	2-s2.0-84984652057
Elibrary:	26671399
Chemical Abstracts:	2015:1718794
Chemical Abstracts (print):	163:669926
OpenAlex:	W1754662869

Citing:

DB	Citing
Web of science	20
Scopus	22
Elibrary	22
OpenAlex	22

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