“Water‐Salt‐in‐Deep Eutectic Solvent” Method to Optimize Conductivity, Viscosity and Freeze Resistance for Eutectic Electrolytes

Deep eutectic solvents have attracted considerable attention due to their unique properties and their potential to replace conventional solvents in diverse applications, such as catalysis, energy storage, and green chemistry. However, despite their broad use, the microscopic mechanisms governing solvation dynamics and the role of hydrogen bonding in deep eutectic solvents remain insufficiently understood. In this article, we present our contributions toward unravelling the micro heterogeneity within deep eutectic solvents by combining vibrational Stark spectroscopy and two-dimensional infrared spectroscopy with molecular dynamics simulations. Our findings demonstrate how the composition, constituents, and addition of water significantly influence the heterogeneous hydrogen bonding network and solvent dynamics within these systems. These insights provide valuable guidance for the design of next-generation solvents tailored to specific applications. By integrating experimental and computational approaches, this work sheds light on the intricate relationship between solvation dynamics and nanostructure in deep eutectic solvents, ultimately paving the way for innovative advances in solvent design.

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Shear rheology senses the electrical room-temperature conductivity optimum in highly Li doped dinitrile electrolytes

Lansab,

Schwan,

Moch

et al. 2024

The Journal of Chemical Physics

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Glutaronitrile (GN) doped with lithium bis(trifluoromethanesulfonyl)imide (LiTFSI) at concentrations below and above the room-temperature conductivity optimum near 1M of Li salt is investigated using dielectric spectroscopy and shear rheology. The experiments are carried out from ambient down to the glass transition temperature Tg, which increases considerably as LiTFSI is admixed to GN. As the temperature is lowered, the conductivity optimum shifts to lower salt concentrations, while the power-law exponents connecting resistivity and molecular reorientation time remain smallest for the 1M composition. By contrast, the rheologically detected time constants, as well as those obtained using dielectric spectroscopy, increase monotonically with increasing Li salt concentration for all temperatures. It is demonstrated that the shear mechanical measurements are, nevertheless, sensitive to the 1M conductivity optimum, thus elucidating the interplay of the dinitrile matrix with the mobile species. The data for the Li doped GN and other nitrile solvents all follow about the same Walden line, in harmony with their highly conductive character. The composition dependent relation between the ionic and the reorientational dynamics is also elucidated.

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“Water‐Salt‐in‐Deep Eutectic Solvent” Method to Optimize Conductivity, Viscosity and Freeze Resistance for Eutectic Electrolytes

Cited by 3 publications

References 27 publications

The exploration of interaction between DES (1 TEAB: 3 EG) and molecular solvents by transfer properties

The exploration of interaction between DES (1 TEAB: 3 EG) and molecular solvents by transfer properties

Solvation Dynamics and Microheterogeneity in Deep Eutectic Solvents

Shear rheology senses the electrical room-temperature conductivity optimum in highly Li doped dinitrile electrolytes

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