Svitlana Zahorulko scite author profile

The electrochemical oxidation of nitrofurazone with SnO2, doped by platinum group metals, and pure PbO2 has been investigated. Тhe oxidation rate of nitrofurazone with PbO2-anode is 5.3 times higher compared to doped SnO2 anodes. It was found that the presence of 1; 2 and 3 g l−1 NaCl in electrolyte affects the efficiency of the electrooxidation process in the case of doped SnO2 anodes, the oxidation rate of nitrofurazone increases by 2.3; 3.7; 5.8 times, respectively. Using of doped SnO2 in chloride-containing media allows one to achieve the same rate of destruction of nitrofurazone as when using lead dioxide. Moreover, SnO2 doped electrodes are characterized by the production of a large number of hypochlorous acid and have a higher service life compared to PbO2 in such harsh conditions.

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The comparative study of electrocatalytic activity of various anode materials in respect to the oxidation of nitroanilines

Zahorulko

Shmychkova

Luk’yanenko

et al. 2019

Materials Today: Proceedings

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Electrochemical oxidation of chloramphenicol with lead dioxide–surfactant composites

Shmychkova

Zahorulko

Luk’yanenko

et al. 2021

Water Environment Research

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The PbO2–2 wt.% sodium dodecyl sulfate composite formed from methanesulfonate electrolyte consists of 93.1% of α‐phase PbO2 in contrast to the similar one synthesized from nitrate electrolyte, which contains 73.3% of β phase. The electrocatalytic activity of the obtained composites in the oxygen evolution reaction and oxidation of chloramphenicol was investigated. It was found that the Tafel slope significantly exceeds the theoretical value, which indicates a decrease in the degree of filling of the electrode surface with oxygen‐containing particles. In the presence of organic compound and chloride ions in the solution, irreversible adsorption of the intermediate is observed, which leads to additional blocking of active centers on the oxide surface, which are involved in the oxidation of organic substance. It was established that the maximum rate of chloramphenicol conversion is 83.5% and 85% at 50 and 80 mA cm−2, respectively, under kinetic control. The heterogeneous oxidation rate constant of chloramphenicol is 0.0035 min−1. Oxidation of chloramphenicol occurs through the formation of 4‐(‐2‐amino‐1,3‐dihydroxy‐propanyl)‐nitrobenzene with cleavage of dichloroacetic acid. Next, the amino group is oxidized to the nitro group to form 4‐(2‐nitro‐1,3‐dihydroxy‐propanyl)‐nitrobenzene. Subsequent electrolysis produces nitrobenzoic acid, which is oxidized to benzoic acid, later hydroquinone, then benzoquinone and a set of aliphatic compounds. Practitioner Points The PbO2–2 wt.% SDS composite consists of 93.1% of α phase of PbO2 in contrast to those synthesized from nitrate electrolyte. The Tafel slope indicates a decrease of surface filling with oxygen‐containing particles. Irreversible adsorption of the intermediate is observed in the presence of chloride ions.

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Assessing English Communicative Competence Via Distant Testing

Zahorulko¹

2020

ALR Journal

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The influence of surfactants on nucleation and physico-chemical properties of lead dioxide

Luk’yanenko¹,

Shmychkova²,

Zahorulko³

et al. 2020

Chem. Met. Alloys

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