posted on 2016-11-14, 00:00authored byT. Jane Stockmann, Ryan Guterman, Paul J. Ragogna, Zhifeng Ding
Ionic
liquids (ILs) have become valuable new materials for a broad
spectrum of applications including additives or components for new
hydrophobic/hydrophilic polymer coatings. However, fundamental information
surrounding IL molecular properties is still lacking. With this in
mind, the microinterface between two immiscible electrolytic solutions
(micro-ITIES), for example, water|1,2-dichloroethane, has been used
to evaluate the hydrophobicity/lipophilicity of 10 alkylphosphonium
ILs. By varying the architecture around the phosphonium core, chemical
differences were induced, changing the lipophilicity/hydrophilicity
of the cations. Ion transfer (IT) within the polarizable potential
window (PPW) was measured to establish a structure–property
relationship. The Gibbs free energy of IT and the solubility of their
ILs were also calculated. For phosphonium cations bearing either three
butyl or three hydroxypropyl groups with a tunable fourth arm, the
latter displayed a wide variety of easily characterizable IT potentials.
The tributylphosphonium ILs, however, were too hydrophobic to undergo
IT within the PPW. Utilizing a micro-ITIES (25 μm diameter)
housed at the tip of a capillary in a uniquely designed pipet holder,
we were able to probe beyond the traditional potential window and
observe ion transfer of these hydrophobic phosphonium ILs for the
first time. A similar trend in lipophilicity was determined between
the two subsets of ILs by means of derived solubility product constants.
The above results serve as evidence of the validation of this technique
for the evaluation of hydrophobic cations that appear beyond the conventional
PPW and of the lipophilicity of their ILs.