posted on 2015-11-10, 00:00authored byJoohyung Lee, Zhang-Lin Zhou, Guillermo Alas, Sven Holger Behrens
Electric charging of colloidal particles
in nonpolar solvents plays
a crucial role for many industrial applications and products, including
rubbers, engine oils, toners, or electronic displays. Although disfavored
by the low solvent permittivity, particle charging can be induced
by added surfactants, even nonionic ones, but the underlying mechanism
is poorly understood, and neither the magnitude nor the sign of charge
can generally be predicted from the particle and surfactant properties.
The conclusiveness of scientific studies has been limited partly by
a traditional focus on few surfactant types with many differences
in their chemical structure and often poorly defined composition.
Here we investigate the surface charging of poly(methyl methacrylate)
particles dispersed in hexane-based solutions of three purified polyisobutylene
succinimide polyamine surfactants with “subtle” structural
variations. We precisely vary the surfactant chemistry by replacing
only a single electronegative atom located at a fixed position within
the polar headgroup. Electrophoresis reveals that these small differences
between the surfactants lead to qualitatively different particle charging.
In the respective particle-free surfactant solutions we also find
potentially telling differences in the size of the surfactant aggregates
(inverse micelles), the residual water content, and the electric solution
conductivity as well as indications for a significant size difference
between oppositely charged inverse micelles of the most hygroscopic
surfactant. An analysis that accounts for the acid/base properties
of all constituents suggests that the observed particle charging is
better described by asymmetric adsorption of charged inverse micelles
from the liquid bulk than by charge creation at the particle surface.
Intramicellar acid–base interaction and intermicellar surfactant
exchange help rationalize the formation of micellar ions pairs with
size asymmetry.