Robust Sulfonated Proton Exchange Membrane from a Poly(styrene-<i>co</i>-divinylbenzene) <i>melt</i>-Interpenetrated Polyethylene Network for Vanadium Redox Flow Batteries
Jeet Sharma, Harun Khan, Prashant Upadhyay, Amit Kumar Rajak, Sarthak Mishra, Nagalakshmi Gayathri M, Ramanujam Kothandaraman, Vaibhav Kulshrestha
Abstract
A low-cost, durable, and efficient proton exchange membrane has been developed via melt -interpenetrating-type networking of poly(styrene- co -divinylbenzene) and polyethylene for vanadium redox flow battery (VRFB) application. The pristine poly(styrene- co -divinylbenzene) interpenetrating polyethylene films were processed using blow-molded extrusion, and the sulfonic acid groups were functionally tailored via a simple room-temperature immersion method. The designed membranes exhibited excellent physicochemical properties and mechanical stabilities in an electrochemical environment. Compared to Nafion-117 (N-117, 41 mΩ), the interpolymer membrane exhibited a cell resistance of ∼26 mΩ and demonstrated high Coulombic efficiency, energy efficiency, and voltage efficiency in the ranges of 93–97, 86–68, and 93–71% when operated between current densities of 50–200 mA cm –2, respectively. Moreover, the kinetic limitations of V 3+ ↔V 2+ conversion were simultaneously addressed using cat. d -fructose in negolyte via transient tailored wettability. With negolyte modifications, the interpolymer membrane illustrated a high specific capacity recovery of ∼98% when operated at 100 mA cm –2 employing a rebalancing method. At 50 mA cm –2 and 100 mA cm –2, the membrane achieved capacities of ∼26 and 25 Ah L –1, which were ∼96 and 93% of theoretical limits (viz., 26.8 Ah L –1 ), respectively. Polarization studies revealed the highest peak power density to be ∼570 mW cm –2, wherein N-117 illustrated capacity, peak power density, and energy efficiencies of 21 Ah L –1, ∼375 mW cm –2, and 80%, respectively. Thus, simultaneous benchmarking in membrane material design and V 2+ ↔V 3+ kinetic limitations were successfully demonstrated to corroborate strong competitive performance for ready-to-scale VRFB devices.