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Electrochemical implications of modulating the solvation shell around redox active organic species in aqueous organic redox flow batteries

Kritika Sharma, Shrihari Sankarasubramanian, Javier Parrondo, Vijay Ramani

2021Proceedings of the National Academy of Sciences23 citationsDOIOpen Access PDF

Abstract

Significance The development of cost-effective batteries for long-duration grid scale energy storage will be accelerated using frameworks to rapidly screen and select battery components. Herein, we show that the solvent reorganization energy calculated from the Born equation (with reference to an electrolyte’s composition) is predictive of the electrolytes’ device level performance. This descriptor was found to correlate with key transport and kinetic properties over a range of electrolyte compositions and pH values, succinctly capturing the multicomponent interactions between the electrolyte salts and solvent. This enables the initial high-throughput screening of electrolyte candidates with minimal experimentation. Applied to aqueous redox flow batteries employing organic redox active species, we predict high-performance electrolyte compositions, enabling significantly enhanced device performance.

Topics & Concepts

ElectrolyteRedoxElectrochemistryFlow batterySolvationAqueous solutionChemistryBattery (electricity)Chemical engineeringInorganic chemistrySolventEnergy storageElectrodeMaterials scienceThermodynamicsOrganic chemistryPhysical chemistryPower (physics)EngineeringPhysicsAdvanced battery technologies researchElectrocatalysts for Energy ConversionAdvanced Battery Materials and Technologies
Electrochemical implications of modulating the solvation shell around redox active organic species in aqueous organic redox flow batteries | Litcius