How Electrical Heterogeneity Parameters of Ion-Exchange Membrane Surface Affect the Mass Transfer and Water Splitting Rate in Electrodialysis

Electrodialysis (ED) has been demonstrated as an effective membrane method for desalination, concentration, and separation. Electroconvection (EC) is a phenomenon which can essentially increase the mass transfer rate and reduce the undesirable water splitting effect. Efforts by a number of researche...

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Autores principales: Zyryanova, Svetlana, Mareev, Semyon, Gil, Violetta, Korzhova, Elizaveta, Pismenskaya, Natalia, Sarapulova, Veronika, Rybalkina, Olesya, Boyko, Evgeniy, Larchet, Christian, Dammak, Lasaad, Nikonenko, Victor
Formato: Online Artículo Texto
Lenguaje:English
Publicado: MDPI 2020
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Article
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7037469/
https://www.ncbi.nlm.nih.gov/pubmed/32024103
http://dx.doi.org/10.3390/ijms21030973
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author Zyryanova, Svetlana
Mareev, Semyon
Gil, Violetta
Korzhova, Elizaveta
Pismenskaya, Natalia
Sarapulova, Veronika
Rybalkina, Olesya
Boyko, Evgeniy
Larchet, Christian
Dammak, Lasaad
Nikonenko, Victor
author_facet Zyryanova, Svetlana
Mareev, Semyon
Gil, Violetta
Korzhova, Elizaveta
Pismenskaya, Natalia
Sarapulova, Veronika
Rybalkina, Olesya
Boyko, Evgeniy
Larchet, Christian
Dammak, Lasaad
Nikonenko, Victor
author_sort Zyryanova, Svetlana
collection PubMed
description Electrodialysis (ED) has been demonstrated as an effective membrane method for desalination, concentration, and separation. Electroconvection (EC) is a phenomenon which can essentially increase the mass transfer rate and reduce the undesirable water splitting effect. Efforts by a number of researchers are ongoing to create conditions for developing EC, in particular, through the formation of electrical heterogeneity on the membrane surface. We attempt, for the first time, to optimize the parameters of surface electrical heterogeneity for ion-exchange membranes used in a laboratory ED cell. Thirteen different patterns on the surface of two Neosepta anion-exchange membranes, AMX and AMX-Sb, were tested. Low-conductive fluoropolymer spots were formed on the membrane surface using the electrospinning technique. Spots in the form of squares, rectangles, and circles with different sizes and distances between them were applied. We found that the spots’ shape did not have a visible effect. The best effect, i.e., the maximum mass transfer rate and the minimum water splitting rate, was found when the spots’ size was close to that of the diffusion layer thickness, δ (about 250 μm in the experimental conditions), and the distance between the spots was slightly larger than δ, such that the fraction of the screened surface was about 20%.
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spelling pubmed-70374692020-03-11 How Electrical Heterogeneity Parameters of Ion-Exchange Membrane Surface Affect the Mass Transfer and Water Splitting Rate in Electrodialysis Zyryanova, Svetlana Mareev, Semyon Gil, Violetta Korzhova, Elizaveta Pismenskaya, Natalia Sarapulova, Veronika Rybalkina, Olesya Boyko, Evgeniy Larchet, Christian Dammak, Lasaad Nikonenko, Victor Int J Mol Sci Article Electrodialysis (ED) has been demonstrated as an effective membrane method for desalination, concentration, and separation. Electroconvection (EC) is a phenomenon which can essentially increase the mass transfer rate and reduce the undesirable water splitting effect. Efforts by a number of researchers are ongoing to create conditions for developing EC, in particular, through the formation of electrical heterogeneity on the membrane surface. We attempt, for the first time, to optimize the parameters of surface electrical heterogeneity for ion-exchange membranes used in a laboratory ED cell. Thirteen different patterns on the surface of two Neosepta anion-exchange membranes, AMX and AMX-Sb, were tested. Low-conductive fluoropolymer spots were formed on the membrane surface using the electrospinning technique. Spots in the form of squares, rectangles, and circles with different sizes and distances between them were applied. We found that the spots’ shape did not have a visible effect. The best effect, i.e., the maximum mass transfer rate and the minimum water splitting rate, was found when the spots’ size was close to that of the diffusion layer thickness, δ (about 250 μm in the experimental conditions), and the distance between the spots was slightly larger than δ, such that the fraction of the screened surface was about 20%. MDPI 2020-02-01 /pmc/articles/PMC7037469/ /pubmed/32024103 http://dx.doi.org/10.3390/ijms21030973 Text en © 2020 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).
spellingShingle Article
Zyryanova, Svetlana
Mareev, Semyon
Gil, Violetta
Korzhova, Elizaveta
Pismenskaya, Natalia
Sarapulova, Veronika
Rybalkina, Olesya
Boyko, Evgeniy
Larchet, Christian
Dammak, Lasaad
Nikonenko, Victor
How Electrical Heterogeneity Parameters of Ion-Exchange Membrane Surface Affect the Mass Transfer and Water Splitting Rate in Electrodialysis
title How Electrical Heterogeneity Parameters of Ion-Exchange Membrane Surface Affect the Mass Transfer and Water Splitting Rate in Electrodialysis
title_full How Electrical Heterogeneity Parameters of Ion-Exchange Membrane Surface Affect the Mass Transfer and Water Splitting Rate in Electrodialysis
title_fullStr How Electrical Heterogeneity Parameters of Ion-Exchange Membrane Surface Affect the Mass Transfer and Water Splitting Rate in Electrodialysis
title_full_unstemmed How Electrical Heterogeneity Parameters of Ion-Exchange Membrane Surface Affect the Mass Transfer and Water Splitting Rate in Electrodialysis
title_short How Electrical Heterogeneity Parameters of Ion-Exchange Membrane Surface Affect the Mass Transfer and Water Splitting Rate in Electrodialysis
title_sort how electrical heterogeneity parameters of ion-exchange membrane surface affect the mass transfer and water splitting rate in electrodialysis
topic Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7037469/
https://www.ncbi.nlm.nih.gov/pubmed/32024103
http://dx.doi.org/10.3390/ijms21030973
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