Litcius/Paper detail

Nonfluorinated membrane with a decentralized ion-transport network enables efficient and sustainable polysulfide redox flow batteries

Feiran Wang, Shuang Luo, Jiafeng Lei, Fei Ai, Ka Lok Leung, Jun Fan, Yi‐Chun Lu

2025Science Advances10 citationsDOIOpen Access PDF

Abstract

Polysulfide-based redox flow batteries are promising for long-duration energy storage, owing to ultralow-cost/earth-abundant active materials and full decoupling of power and energy. However, their practical application has been prevented by poor cycle life resulting from polysulfide crossover and a heavy reliance on costly fluorinated membranes (Nafion 117, USD $800 to $3500 per square meter), along with the environmental concerns. Here, we develop a nonfluorinated sulfonated polyethersulfone (SPES)-based membrane with decentralized ion-transport channels, achieving a 20 times higher ionic selectivity at a markedly reduced cost (USD $12 to $66 per square meter) compared to the commercial Nafion membrane. The low-cost SPES-based membrane enabled stable cycling of polysulfide-ferrocyanide redox flow batteries with a high coulombic efficiency (>99.9%) and energy efficiency (average >75%) for 1600 cycles (>6 months). This strategy demonstrated polysulfide-based redox flow batteries with a record longevity using a low-cost and sustainable membrane, paving the way for their practical commercialization.

Topics & Concepts

PolysulfideFaraday efficiencyRedoxMembraneDecoupling (probability)Materials scienceNafionEnergy storageChemical engineeringFlow (mathematics)NanotechnologyFlow batteryIonic bondingProcess engineeringChemistryEnvironmental scienceSustainable energyFlue-gas desulfurizationEnergy recoveryGraphyneAdvanced battery technologies researchMembrane-based Ion Separation TechniquesMembrane Separation Technologies