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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

2024ACS Applied Energy Materials13 citationsDOI

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.

Topics & Concepts

DivinylbenzeneMaterials scienceMembraneVanadiumFlow batteryStyreneChemical engineeringNafionSulfonic acidPolymer chemistryFaraday efficiencyPolyethyleneElectrochemistryCopolymerPolymerElectrodeChemistryComposite materialElectrolytePhysical chemistryBiochemistryMetallurgyEngineeringAdvanced battery technologies researchSupercapacitor Materials and FabricationFuel Cells and Related Materials