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Magnesium Battery Electrolytes with Improved Oxidative Stability Enabled by Selective Solvation in Fluorinated Solvents

Nathan Hahn, Ethan P. Kamphaus, Ying Chen, Vijayakumar Murugesan, Karl T. Mueller, Lei Cheng, Kevin R. Zavadil

2023ACS Applied Energy Materials21 citationsDOIOpen Access PDF

Abstract

Practical Mg batteries require electrolytes that are stable both toward reduction by Mg metal and oxidation by high voltage cathodes. State-of-the-art Mg electrolytes based on weakly coordinating Mg salts utilize standard ether-type solvents (usually glymes) due to their reductive stability. However, the oxidative stabilities of these solvents are less than ideal, leading to difficulties in realizing the high oxidative stabilities of recently developed salts. On the other hand, alternative solvents with greater oxidative stability are typically unable to support Mg cycling. In this work, we report a selective solvation approach involving the combination of glyme and hydrofluoroether solvents. Selective solvation of Mg 2+ by the glyme solvent component increases the oxidative stability of the glyme while maintaining sufficient reductive stability of the non-coordinating hydrofluoroether. We show that this approach enables the design of electrolytes with greater oxidative stability than glyme-only electrolytes while retaining enough reductive stability to cycle Mg metal. We also relate the influence of various coordination interactions among the solvents and anions with Mg 2+ to their electrochemical stabilities to better inform the design of future electrolytes.

Topics & Concepts

ElectrolyteSolvationChemistryElectrochemistrySolventOxidative phosphorylationMetalBattery (electricity)Inorganic chemistryCombinatorial chemistryOrganic chemistryElectrodePhysical chemistryPhysicsQuantum mechanicsBiochemistryPower (physics)Inorganic Chemistry and MaterialsLayered Double Hydroxides Synthesis and ApplicationsInorganic Fluorides and Related Compounds