Issue 31, 2022

Unravelling free volume in branched-cation ionic liquids based on silicon

Abstract

The branching of ionic liquid cation sidechains utilizing silicon as the backbone was explored and it was found that this structural feature leads to fluids with remarkably low density and viscosity. The relatively low liquid densities suggest a large free volume in these liquids. Argon solubility was measured using a precise saturation method to probe the relative free volumes. Argon molar solubilities were slightly higher in ionic liquids with alkylsilane and siloxane groups within the cation, compared to carbon-based branched groups. The anion size, however, showed by far the dominant effect on argon solubility. Thermodynamic solvation parameters were derived from the solubility data and the argon solvation environment was modelled utilizing the polarizable CL&Pol force field. Semiquantitative analysis was in agreement with trends established from the experimental data. The results of this investigation demonstrate design principles for targeted ionic liquids when optimisation for the free volume is required, and demonstrate the utility of argon as a simple, noninteracting probe. As more ionic liquids find their way into industrial processes of scale, these findings are important for their utilisation in the capture of any gaseous solute, gas separation, or in processes involving the transformation of gases or small molecules.

Graphical abstract: Unravelling free volume in branched-cation ionic liquids based on silicon

Supplementary files

Article information

Article type
Edge Article
Submitted
23 Mar 2022
Accepted
02 Jul 2022
First published
05 Jul 2022
This article is Open Access

All publication charges for this article have been paid for by the Royal Society of Chemistry
Creative Commons BY-NC license

Chem. Sci., 2022,13, 9062-9073

Unravelling free volume in branched-cation ionic liquids based on silicon

E. Bakis, K. Goloviznina, I. C. M. Vaz, D. Sloboda, D. Hazens, V. Valkovska, I. Klimenkovs, A. Padua and M. Costa Gomes, Chem. Sci., 2022, 13, 9062 DOI: 10.1039/D2SC01696F

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