Abstract
The development of Ca conducting electrolytes is key to enable functional rechargeable Ca batteries. The here presented screening strategy is initially based on a combined density functional theory (DFT) and conductor-like screening model for real solvents (COSMO-RS) approach, which allows for a rational selection of electrolyte solvent based on a set of physico-chemical and electrochemical properties: solvation power, electrochemical stability window, viscosity, and flash and boiling points. Starting from 81 solvents, N,N-dimethylformamide (DMF) was chosen as solvent for further studies of cation-solvent interactions and subsequent comparisons vs. cation-anion interactions possibly present in electrolytes, based on a limited set of Ca-salts. A Ca2+ first solvation shell of [Ca(DMF)8]2+ was found to be energetically preferred, even as compared to ion-pairs and aggregates, especially for PF6− and TFSI as the anions. Overall, this points to Ca(TFSI)2 and Ca(PF6)2 dissolved in DMF to be a promising base electrolyte for Ca batteries from a physico-chemical point-of-view. While electrochemical assessments certainly are needed to verify this promise, the screening strategy presented is efficient and a useful stepping-stone to reduce the overall R&D effort.
Highlights
Batteries based on multivalent chemistry have emerged as promising alternatives and complements to the currently dominant lithium-ion battery (LIB) technology, mainly due to foreseen high volumetric capacities and improved safety [1,2,3,4]
The relative salt solubilites were normalized vs. DMSO and the lowest were obtained for the fluorine containing solvents, which is quite natural as fluorine is an electron-withdrawing group that decreases the solvent donor number (DN) and lowers the cation solvation ability[39]
Donor interaction solvents act as Lewis bases towards cations and the DN is a measure of the Lewis basicity
Summary
Batteries based on multivalent chemistry have emerged as promising alternatives and complements to the currently dominant lithium-ion battery (LIB) technology, mainly due to foreseen high volumetric capacities and improved safety [1,2,3,4]. For any modern multivalent rechargeable battery technology the optimization of the electrolyte composition and studies of the resulting performance, must be based on considering several basic physico-chemical and electrochemical properties such as: electrochemical stability window (ESW), ionic conductivity, salt solubility, viscosity, flash and boiling points, etc [1,8,9]. These properties are largely determined by the choices made for salt and solvent(s) and the salt concentration, and affect the viability of efficient Ca metal plating/stripping. There are, still challenges to overcome; temperature dependence [7], cycling efficiency, oxidation stability [10], etc., which calls for effective strategies to develop new Ca conducting electrolytes
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