This communication documents the first case of a solvation regulation strategy for improving the AORFB cycling lifetime by exploiting the ion pairing and hydration effect of supporting electrolytes.
An MXene/POP hybrid material with abundant redox-active sites was prepared through an in situ growth strategy and exhibited high specific capacitance, excellent rate performance, and outstanding long-term cycling stability for pseudocapacitors.
In operando techniques allow for real-time monitoring to elucidate mechanisms, assess degradation rates, and optimize functionality of redox-flow batteries.
Mixing different anthraquinone enhances the solubility and stability of aqueous organic flow battery electrolytes by suppression of aggregation. This can enable higher energy density, longer-lasting, and cost-effective large-scale energy storage.
Quinones are prime candidates for aqueous redox flow batteries. This review discusses the chemistry of quinones and degradation pathways in aqueous solution, illuminating their pathway to successful implementation through case studies and examples.