Evaluation of the Effect of Electroosmosis on the Efficiency of Electrobaromembrane Separation with Track-Etched Membranes

IF 2 Q4 CHEMISTRY, PHYSICAL

Membranes and Membrane Technologies Pub Date : 2023-10-01 DOI:10.1134/S2517751623050025

D. Yu. Butylskii, S. A. Mareev, I. I. Ryzhkov, M. Kh. Urtenov, P. Yu. Apel, V. V. Nikonenko

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Abstract

The results of a theoretical analysis of the influence of the electroosmotic flow on the electromigration and convective transport of competing ions separated by the electrobaromembrane process are presented. Separated ions of the same charge sign move in an electric field through the pores of a track-etched membrane to the corresponding electrode, while a commensurate convective counterflow being created by the pressure drop across the membrane. A simplified model based on the convective electrodiffusion equation and the Hagen–Poiseuille equation allows the analysis of experimental data using only the effective transport numbers of ions in the membrane as fitting parameters. Using a 2D mathematical model described by the system of Nernst–Planck, Navier–Stokes, and Poisson equations, it is shown that the electroosmotic flow can cause the effective transport numbers of competing ions to exceed their values in solution, even if these ions are coions for the membrane.

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电渗透对轨迹刻蚀电压膜分离效率影响的评价

给出了电渗流对电压膜过程中分离的竞争离子的电迁移和对流输运影响的理论分析结果。具有相同电荷符号的分离离子在电场中通过轨迹蚀刻膜的孔隙移动到相应的电极，同时通过膜上的压降产生相应的对流逆流。基于对流电扩散方程和Hagen–Poiseuille方程的简化模型允许仅使用离子在膜中的有效输运数作为拟合参数来分析实验数据。使用由Nernst–Planck、Navier–Stokes和Poisson方程组描述的2D数学模型，表明电渗流可以导致竞争离子的有效传输数超过其在溶液中的值，即使这些离子是膜的离子。

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来源期刊

Membranes and Membrane Technologies Multiple-

CiteScore

3.10

自引率

31.20%

发文量

期刊介绍： The journal Membranes and Membrane Technologies publishes original research articles and reviews devoted to scientific research and technological advancements in the field of membranes and membrane technologies, including the following main topics:novel membrane materials and creation of highly efficient polymeric and inorganic membranes;hybrid membranes, nanocomposites, and nanostructured membranes;aqueous and nonaqueous filtration processes (micro-, ultra-, and nanofiltration; reverse osmosis);gas separation;electromembrane processes and fuel cells;membrane pervaporation and membrane distillation;membrane catalysis and membrane reactors;water desalination and wastewater treatment;hybrid membrane processes;membrane sensors;membrane extraction and membrane emulsification;mathematical simulation of porous structures and membrane separation processes;membrane characterization;membrane technologies in industry (energy, mineral extraction, pharmaceutics and medicine, chemistry and petroleum chemistry, food industry, and others);membranes and protection of environment (“green chemistry”).The journal has been published in Russian already for several years, English translations of the content used to be integrated in the journal Petroleum Chemistry. This journal is a split off with additional topics.