Understanding the influence of ethylene glycol on the microscopic behavior of imidazolium-based monocationic and dicationic ionic liquid

In the present work, the influence of a molecular co-solvent, ethylene glycol (EG) on the microscopic behaviour of an imidazolium-based dicationic ionic liquid (DIL) is analysed by employing time-resolved fluorescence anisotropy (TRFA) and nuclear magnetic resonance (NMR) spectroscopic techniques. In order to have a clear understanding of the specific role of DIL, a mono-cationic ionic liquid (MIL) containing an alkyl side chain unit, same as the alkyl spacer chain length of DIL, has also been investigated. The rotational diffusion of two fluo-rescent probes 9-PA and R110 have been carried out in both neat MIL and DIL and their mixtures with various fractions of EG. The analysis of the results has demonstrated that, within the studied concentration range, the microstructure of MIL encompassing both polar and nonpolar domains gets disrupted as the mole fraction of EG increases. However, a similar investigation in DIL has revealed that the micro-structure of DIL gets affected slightly when similar proportions of EG are added to DIL. This behaviour of DIL is attributed to the enhanced rigidity of the DIL structure due to its folded structural arrangements. Furthermore, NMR studies have provided additional insights into the interactions between the components of ILs and the added solvent. It has been observed that EG can form strong hydrogen-bonding interactions with the imidazolium-ring and alkyl chain protons of MIL. However, such interaction has not been observed in DIL. Moreover, the translational diffusion coefficient (Dt) value for the cationic moiety of both MIL and DIL, measured through NMR, has depicted that in the presence of EG, the change in Dtvalue is much higher for MIL than that for DIL. Overall, the outcome of the combined fluorescence and NMR studies have pointed out that the behaviour of DIL and MIL in the presence of a co-solvent is very different from one another and thus the individual mixture (IL+solvent) can be used for various targeted industrial applications.