Exploration of phase diagram, structural and dynamic behavior of [HMG][FSI] mixtures with NaFSI across an extended composition range

Karolina Biernacka, Faezeh Makhlooghiazad, Ivan Popov, Haijin Zhu, Jean Noël Chotard, Luke A. O’Dell, Alexei P. Sokolov, Jennifer M. Pringle, Maria Forsyth

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Abstract

Hexamethylguanidinium bis(fluorosulfonyl)imide ([HMG][FSI]) has recently been shown to be a promising solid state organic ionic plastic crystal with potential application in advanced alkali metal batteries. This study provides a detailed exploration of the structural and dynamic behavior of [HMG][FSI] mixtures with the sodium salt NaFSI across the whole composition range from 0 to 100 mol%. All mixtures are solids at room temperature. A combination of differential scanning calorimetry (DSC), synchrotron X-ray diffraction (SXRD) and multinuclear solid state NMR spectroscopy is employed to identify a partial phase diagram. The 25 mol% NaFSI/75 mol% [HMG][FSI] composition presents as the eutectic composition with the eutectic transition temperature at 44 °C. Both DSC and SXRD strongly support the formation of a new compound near 50 mol% NaFSI. Interestingly, the 53 mol% NaFSI [HMG][FSI] composition was consistently found to display features of a pure compound whereas the 50 mol% materials always showed a second phase. Many of the compositions examined showed unusual metastable behaviour. Moreover, the ion dynamics as determined by NMR, indicate that the Na+ and FSI anions are signifcantly more mobile than the HMG cation in the liquid state (including the metastable state) for these materials.

Original languageEnglish
Pages (from-to)16712-16723
Number of pages12
JournalPhysical Chemistry Chemical Physics
Volume24
Issue number27
DOIs
StatePublished - Jun 18 2022

Funding

This work was financially supported by the Australian Research Council through the ARC Centre of Excellence for Electromaterials Science (grant no. CE140100012) and through the ARC Training Centre in Future Energy Storage Technologies IC180100049 (StorEnergy). An Australian Synchrotron beamtime allocation & SXRD beamline scientist (Dr Anita D'Angelo) are also acknowledged. The authors also wish to thank Dr Colin Kang (Deakin Univeristy, IFM) for assistance with the materials synthesis. The U.S. team acknowledges financial support from NSF Chemistry program (CHE-2102425 award).

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