posted on 2020-12-15, 13:49authored byJongmin Q. Kim, Soonyong So, Hee-Tak Kim, Siyoung Q. Choi
In vanadium redox flow batteries
(VRFBs), a perfluorinated sulfonic
acid (PFSA) ionomer membrane plays a crucial role in transporting
ions through hydrophilic channels. However, its randomly interconnected
channels with relatively large size in a hydrated state cause low
proton/vanadium ion selectivity, imposing a limitation in enhancing
performance of VRFB. Herein, we develop an ultrathin PFSA membrane
of highly aligned ion channels with reduced size, by molecular arrangement
on the air/water interface. Well-ordered ion channels dramatically
suppress the vanadium ion crossover, enhancing 500-fold in the ion
selectivity compared to conventional PFSA membranes. The molecularly
controlled ultrathin PFSA membranes exhibit stable cell performance
on a porous support over various current densities and long-term cycles
(800 cycles), exceeding the energy efficiency of Nafion 211 (73%)
at 200 mA/cm2. Highly ordered ultrathin PFSA membranes
with high ion selectivity could offer a practically applicable low-cost,
yet high-performance membrane for VRFBs.