Factors Affecting Hydroxide Ion Concentrations in Bipolar Membranes

Q2 Materials Science

Journal of Membrane Science and Research Pub Date : 2021-01-26 DOI:10.22079/JMSR.2021.521613.1433

Yingying Chen, J. Baygents, D. Gervasio, J. Farrell

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引用次数: 1

Abstract

The useful lifetime of bipolar ion exchange membranes is often limited by nucleophilic attack by hydroxide ions on the ionic groups and polymer backbone in the anion exchange layers (AELs). This is especially problematic in water treatment applications for making acid and base from salt solutions. This research investigated the effect of bulk electrolyte composition, current density, membrane thickness, ion exchange capacity, and bulk solution pH value on hydroxide ion concentrations inside the AELs of a bipolar membrane. One-dimensional Nernst-Plank equations were solved for the species Na+, Cl-, OH- and H+ within 20-100 µm thick anion and cation exchange layers with fixed charged densities ranging from 0.5-2.0 eq/L. In 1 M NaCl solutions at neutral pH values, hydroxide concentrations in the AEL reached as high as 2.2 M at a current density of 100 mA/cm2. In 1 M NaOH solutions, hydroxide ion concentrations reached as high as 3.77 M. Hydroxide concentrations in the AEL were significantly affected by the ratio of Cl- to hydroxide ions in the bulk electrolyte. Where hydroxide concentrations in the bulk electrolyte were an order of magnitude lower than chloride concentrations, membrane hydroxide concentrations were nearly proportional to the current density. Increases in ion exchange capacity and AEL thickness resulted in increased membrane hydroxide ion concentrations. Membrane concentrations of hydroxide ions can be minimized by operation at low current densities, with high background electrolyte concentrations using thin membranes with low ion exchange capacities and producing base concentrations less than 0.1 M.

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影响双极膜中氢氧离子浓度的因素

双极性离子交换膜的使用寿命通常受到氢氧化物离子对阴离子交换层中离子基和聚合物主链的亲核攻击的限制。这在从盐溶液制取酸和碱的水处理应用中尤其成问题。本研究考察了电解质组成、电流密度、膜厚度、离子交换容量和溶液pH值对双极膜AELs内氢氧根离子浓度的影响。在20-100µm厚的阴离子和阳离子交换层中，在0.5-2.0 eq/L的固定电荷密度范围内，求解了Na+、Cl-、OH-和H+的一维Nernst-Plank方程。在中性pH值为1 M的NaCl溶液中，当电流密度为100 mA/cm2时，AEL中的氢氧化物浓度高达2.2 M。在1 M NaOH溶液中，氢氧根离子浓度高达3.77 M, AEL中氢氧根离子浓度受体电解质中Cl-与氢氧根离子比例的显著影响。当本体电解质中的氢氧化物浓度比氯化物浓度低一个数量级时，膜上的氢氧化物浓度几乎与电流密度成正比。离子交换容量和AEL厚度的增加导致氢氧化膜离子浓度的增加。在低电流密度下，使用低离子交换能力的薄膜，在高背景电解质浓度下，产生的碱浓度小于0.1 M，可以使氢氧化物离子的膜浓度最小化。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Membrane Science and Research Materials Science-Materials Science (miscellaneous)

CiteScore

4.00

自引率

0.00%

发文量

审稿时长

8 weeks

期刊介绍： The Journal of Membrane Science and Research (JMSR) is an Open Access journal with Free of Charge publication policy, which provides a focal point for academic and industrial chemical and polymer engineers, chemists, materials scientists, and membranologists working on both membranes and membrane processes, particularly for four major sectors, including Energy, Water, Environment and Food. The journal publishes original research and reviews on membranes (organic, inorganic, liquid and etc.) and membrane processes (MF, UF, NF, RO, ED, Dialysis, MD, PV, CDI, FO, GP, VP and etc.), membrane formation/structure/performance, fouling, module/process design, and processes/applications in various areas. Primary emphasis is on structure, function, and performance of essentially non-biological membranes.