Catalysis and petrochemistry
Theoretical and scientific-technical collection
ISSN 2707-5796 (Online), ISSN 2412-4176 (Print)
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Kataliz ta naftohimia: 2020, Vol.30, 83-89.

https://doi.org/10.15407/kataliz2020.30.083

Kinetics of catalytic oxidation 4-bromethylbenzene by ozone in acetic acid

Skorokhod K. S., Galstyan A. G.

National Aviation University of the National Academy of Sciences of Ukraine 03058, Ukraine, Kyiv, ave. Lubomira Guzara, 1, E-mail: aggaalst@gmail.com

ABSTRACT

The kinetic regularities of catalytic oxidation of 4-bromoethylbenzene by ozone to create an eco-logical, low-temperature technology for the synthesis of 4-bromoacetophenone have been studied. The experiment was performed in a glass reactor with a porous membrane under conditions of kinetic regime at a temperature of 293-333 K. The concentration of ozone in the gas phase was determined by spectrophotometric method. Analysis of 4-bromoacetophenone and its oxidation products was performed by gas-liquid chromatography. Oxidation of 4-bromoethylbenzene by ozone in a solution of acetic acid at a temperature of 293 K in the presence of catalytic impurities of manganese (II) ace-tate proceeds mainly on the ethyl group with the formation of a mixture of 4-bromoacetophenone (95.6 %) and 1-(4-bromophenylethanoacetate 4.2 % ). Prevention of destructive oxidation of the ben-zene ring (ozonolysis) with the involvement of the catalyst is explained by the fact that ozone under ca-talysis mainly reacts with a salt of manganese (II) and not with the substrate to form the active form of manganese Mn(IV) which has high substrate selectivity to alkylarenes, directs the oxidation of 4-bromoethylbenzene to the ethyl group. High selectivity of side chain oxidation is achieved only at ele-vated catalyst concentrations, which is largely due to the higher reaction rate of the substrate with ozone than with Mn(IV). The composition of the products of catalytic oxidation of 4-bromoethylbenzene depends on the temperature: at 293 K the reaction stops at the stage of formation of the corresponding ketone and acylated alcohol, increasing the temperature promotes further oxidation of 4-bromoacetophenone to 4-bromobenzoic acid, thus forming a mixture containing 4-bromoacetophenone (82.5 %), 1-(4-bromophenyl)ethanolacetate (4.2 %) and 4-bromo-benzoic acid (11.8 %). The research allowed to formulate general regularities of the reaction of catalytic oxidation of 4-bromomethylbenzene by ozone in acetic acid, to explain the role of the catalyst in the system and to propose a chemical scheme of oxidation corresponding to experimental data.

KEYWORDS

catalyst, transition metal salts, oxidation, ozone, ozonolysis, kinetics, 4-bromoethylbenzene, 4-bromoacetophenone, 1-(4-bromophenyl)ethanolacetate, acetic acid.

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