School of Environmental Science and Engineering, Gwangju Institute of Science and Technology (GIST), 123 Cheomdan-Gwagiro (Oryong-dong), Buk-gu, Gwangju 500-712, Korea.
Environ Sci Technol. 2015 Jul 21;49(14):8872-7. doi: 10.1021/acs.est.5b01151. Epub 2015 Jul 7.
A low-resistance ion-exchange membrane is essential to achieve the high-performance energy conversion or storage systems. The formation methods for low-resistance membranes are various; one of the methods is the ion channel alignment of an ion-exchange membrane under a direct current (DC) electric field. In this study, we suggest a more effective alignment method than the process with the DC electric field. First, an ion-exchange membrane was prepared under a pulsed electric field [alternating current (AC) mode] to enhance the effectiveness of the alignment. The membrane properties and the performance in reverse electrodialysis (RED) were then examined to assess the membrane resistance and ion selectivity. The results show that the membrane electrical resistance (MER) had a lower value of 0.86 Ω cm(2) for the AC membrane than 2.13 Ω cm(2) observed for the DC membrane and 4.30 Ω cm(2) observed for the pristine membrane. Furthermore, RED achieved 1.34 W/m(2) of maximum power density for the AC membrane, whereas that for the DC membrane was found to be 1.14 W/m(2) [a RED stack assembled with CMX, used as a commercial cation-exchange membrane (CEM), showed 1.07 W/m(2)]. Thereby, the novel preparation process for a remarkable low-resistance membrane with high ion selectivity was demonstrated.
低电阻离子交换膜对于实现高性能的能量转换或存储系统至关重要。低电阻膜的形成方法多种多样;其中一种方法是在直流(DC)电场下对离子交换膜进行离子通道对齐。在这项研究中,我们提出了一种比直流电场处理更有效的对齐方法。首先,在脉冲电场[交流(AC)模式]下制备离子交换膜,以增强对齐的效果。然后检查膜的性能和在反向电渗析(RED)中的性能,以评估膜电阻和离子选择性。结果表明,交流膜的膜电阻(MER)值较低,为 0.86 Ω·cm²,而直流膜为 2.13 Ω·cm²,原始膜为 4.30 Ω·cm²。此外,对于交流膜,RED 达到了 1.34 W/m²的最大功率密度,而对于直流膜,其功率密度为 1.14 W/m²[由 CMX 组装的 RED 堆栈,用作商业阳离子交换膜(CEM),其功率密度为 1.07 W/m²]。因此,展示了一种具有高离子选择性的显著低电阻膜的新型制备工艺。