Abstract
The amphiphilic ionic liquids containing an alkyl chain in molecules form nano-structure in the bulk, although they also show surface activity and form aggregates in aqueous solutions. Although insights into the layer structures of ionic liquids were obtained using X-ray and neutron scattering techniques, the nanostructures of ionic liquids remain unclear. Herein, the surface adsorption and bulk properties of homogeneous polyoxyethylene (EO)-type nonionic surfactants (C(x)EO(6); x = 8, 12, or 16) were elucidated in quaternary-ammonium-salt-type amphiphilic gemini ionic liquids with oxygen or nitrogen-containing spacers [2C(n)(Spacer) NTf(2); (Spacer) = (2-O-2), (2-O-2-O-2), (2-N-2), (2/2-N-2), (3), (5), or (6); n = 10, 12, or 14 for (2-O-2) and n = 12 for all other spacers] by surface tension, small- and wide-angle X-ray scattering, cryogenic transmission electron microscopy, and viscosity measurements. The surface tension of C(12)EO(6) in 2C(n)(Spacer) NTf(2) with oxygen-containing spacers increased with increasing concentration of C(12)EO(6), becoming close to that of C(12)EO(6) alone, indicating that the amphiphilic ionic liquid adsorbed at the interface was replaced with C(x)EO(6). In contrast, both 2C(n)(Spacer) NTf(2) with nitrogen-containing spacers and nonionic surfactants remained adsorbed at the interface at high concentrations. In the bulk, it was found that 2C(n)(Spacer) NTf(2) formed layer structures, in which the spacing depended on the alkyl chain length of C(x)EO(6). These insights are expected to advance the practical applications of amphiphilic ionic liquids such as ion permeation, drug solubilization, and energy delivery systems.