posted on 2017-10-10, 00:00authored byVeena
T. Kelleppan, Jackson E. Moore, Thomas M. McCoy, Anna V. Sokolova, Liliana de Campo, Brendan L. Wilkinson, Rico F. Tabor
Long-chain amidopropyl
betaines are known for their ability to
self-assemble into viscoelastic wormlike micellar structures. Here,
we explore the effect of tailgroup molecular architecture on this
process, comparing five molecules, each with C18 chains but different
levels of unsaturation and branching. The surfactants are synthesized
from stearic, oleic, linoleic, linolenic, and isostearic acids. The
self-assembly of these molecules in aqueous solutions is explored
using small- and ultra-small-angle neutron scattering (SANS and USANS).
It is seen that optimum wormlike micelle formation is achieved for
the oleic-chained surfactant, and the alignment of self-assembled
structures is further explored using rheo-SANS. The more highly unsaturated
molecules form rodlike micelles, whereas the stearic-tailed molecule
shows a pronounced Krafft point and the isostearic-chained surfactant
is entirely water-insoluble. These results demonstrate the critical
importance of tailgroup geometry on surfactant properties and self-assembly
for this industrially important class of surfactants.