Теоретический анализ вольтамперной характеристики нестационарного переноса 1:1 электролита в мембранных системах с учетом электроконвекции и реакции диссоциации/рекомбинации воды
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Научный журнал Моделирование, оптимизация и информационные технологииThe scientific journal Modeling, Optimization and Information Technology
Online media
issn 2310-6018

Theoretical analysis of the current-voltage characteristic of the unsteady 1:1 transfer of an electrolyte in membrane systems, taking into account electroconvection and the dissociation/recombination reaction of water

idKovalenko A.V., Gudza I.V.,  Pismenskiy A.V.,  idChubyr N.O., idUrtenov M.K.

UDC 519.87+004.421
DOI: 10.26102/2310-6018/2021.34.3.011

  • Abstract
  • List of references
  • About authors

The current-voltage characteristic (CVC) is an important integral characteristic of the salt ion transfer process in electromembrane systems, which are considered as the desalination channel of the electrodialysis apparatus. The article examines the theoretical current-voltage characteristic, for the calculation of which a new 2D mathematical model of non-stationary 1:1 transfer of an electrolyte in a potentiodynamic mode is formulated and numerically solved, taking into account the electroconvection and non-catalytic reaction of dissociation and recombination of water molecules. The main regularities of changes in the current-voltage characteristic and their connection with the electroconvection and non-catalytic reaction of dissociation and recombination of water molecules are established. It is shown that before the occurrence of electroconvection, the values of CVC, taking into account the dissociation/recombination reaction of water molecules, are higher than the values of CVC without taking into account this reaction. This difference is caused by the effect on the electric field strength of the products of water dissociation, i.e., the exaltation of the limiting current. Electroconvection begins later, taking into account the dissociation/recombination reaction of water molecules, than without taking into account this reaction. At higher values of the potential jump, the values of the VAC taking into account the dissociation/recombination reaction of water molecules are lower than the values of the CVC without taking into account this reaction. It is established that the non-solenoidal part of the current is small, so the total current and the solenoid part of the current coincide with good accuracy, both in the case of taking into account and in the case without taking into account the dissociation/recombination reaction of water molecules. Thus, in the first approximation, the total current can be considered as the solenoid part of the current, which is calculated using a double integral that is resistant to rounding errors in spatial variables, but retains all the features of the change in current density over time.

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Kovalenko Anna Vladimirovna
Dr. Sci, associate professor

WoS | Scopus | ORCID | eLibrary |

Kuban State University

Krasnodar, Russia

Gudza Inna Vladimirovna

Kuban State University

Krasnodar, Russia

Pismenskiy Alexander Vladimirovich
Cand.Sci. (Phys.–Math.)

Kuban State University

Krasnodar, Russia

Chubyr Natalia Olegovna,
Cand.Sci. (Phys.–Math.), associate professor

ORCID | eLibrary |

Kuban State Technological University

Krasnodar, Russia

Urtenov Makhamet Khuseevich
Dr. Sci. (Phys.–Math.), Professor

ORCID | eLibrary |

Kuban State University

Krasnodar, Russia

Keywords: current-voltage characteristic, membrane systems, mathematical model, cross-section of the desalting channel, ion-exchange membrane

For citation: Kovalenko A.V., Gudza I.V., Pismenskiy A.V., Chubyr N.O., Urtenov M.K. Theoretical analysis of the current-voltage characteristic of the unsteady 1:1 transfer of an electrolyte in membrane systems, taking into account electroconvection and the dissociation/recombination reaction of water. Modeling, Optimization and Information Technology. 2021;9(3). URL: https://moitvivt.ru/ru/journal/pdf?id=1014 DOI: 10.26102/2310-6018/2021.34.3.011 (In Russ).

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Full text in PDF

Received 29.06.2021

Revised 14.09.2021

Accepted 23.09.2021

Published 30.09.2021