Reducing Ohmic Resistances in Membrane Capacitive Deionization Using Micropatterned Ion‐Exchange Membranes, Ionomer Infiltrated Electrodes, and Ionomer‐Coated Nylon Meshes

Mahmudul Hasan, Bharat Shrimant, Colton Burke Waters, C. Gorski, C. Arges
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Abstract

Membrane capacitive deionization (MCDI) is an emerging water desalination platform that is compact, electrified, and does not require high‐pressure piping. Herein, highly conductive poly(phenylene alkylene) ion‐exchange membranes (IEMs) are micropatterned with different surface geometries for MCDI. The micropatterned membranes increase the interfacial area with the liquid stream leading to a 700 mV reduction in cell voltage when operating at constant current (2 mA cm−2; 2000 ppm NaCl feed) while improving the energy normalized adsorbed salt (ENAS) value by 1.4 times. Combining the micropatterned poly(phenylene alkylene) IEMs with poly(phenylene alkylene) ionomer‐filled electrodes reduces the cell voltage by 1000 mV and improves the ENAS values by 2.3 times relative to the base case. This reduction in cell voltage allows for higher current density operation (i.e., 3–4 mA cm−2) . The reduction in cell voltage is ascribed to the ameliorating ohmic resistances related to ion transport at the membrane‐process stream interface and in the carbon cloth electrode. Finally, porous ionic conductors are implemented into the spacer channel with flat and micropatterned IEM configurations and ionomer infiltrated electrodes. For the configuration with flat IEMs, the porous ionic conductor improves ENAS values across the current density regime (2–4 mA cm−2), while for micropatterned IEMs it gets improved only at 4 mA cm−2.

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使用微图案离子交换膜、离子聚合物浸润电极和离子聚合物涂层尼龙网降低膜电容式去离子过程中的欧姆电阻
膜电容去离子(MCDI)是一种新兴的海水淡化平台,它结构紧凑、电气化且无需高压管道。在这里,高导电性聚(苯基烯烃)离子交换膜(IEM)被微图案化,具有不同的表面几何形状,可用于 MCDI。微图案膜增加了与液流的界面面积,在恒定电流(2 mA cm-2;2000 ppm NaCl 进料)下运行时,电池电压降低了 700 mV,同时能量归一化吸附盐(ENAS)值提高了 1.4 倍。将微图案聚苯烯 IEM 与填充聚苯烯离聚物的电极相结合,可将电池电压降低 1000 mV,并将 ENAS 值提高 2.3 倍。电池电压的降低允许更高的电流密度运行(即 3-4 mA cm-2)。电池电压的降低可归因于膜-工艺流界面和碳布电极中与离子传输有关的欧姆电阻的改善。最后,多孔离子导体通过平面和微图案 IEM 配置以及离子聚合物浸润电极进入间隔通道。对于平面 IEM 配置,多孔离子导体可改善整个电流密度范围(2-4 mA cm-2)内的 ENAS 值,而对于微图案 IEM,只有在 4 mA cm-2 时才会有所改善。
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