The cylindrical micelles formed by amphiphilic surfactants
in aqueous
media generally organize in two-dimensional (2D) hexagonal lattice
because of their largely circular cross section. Here we demonstrate
that the packing habit of the cylindrical micelles of anionic sodium
dodecyl sulfate (SDS) was perturbed by the electrostatic binding with
a positively charged poly(amidoamine) (PAMAM) G4 dendrimer via cooperative
deformation for charge matching, leading to the ribbon phase with
nonhexagonal 2D lattices. The cylindrical micelles with elliptic cross
section packed in the centered rectangular lattice with orthorhombic cmm symmetry over a broad range of surfactant-to-dendrimer
amine group molar ratio. The packing structure transformed to the
oblique lattice with monoclinic p2 symmetry at the
stoichiometric composition. Detailed analysis of the geometry of the
dendrimers accommodated in the interstitial tunnels surrounded by
the SDS cylinders revealed that the dendrimer molecules were elongated
into prolate ellipsoids along the long axis of the cylinder for enhancing
charge matching. The degree of deformation was governed by the interplay
among the electrostatic free energies and the elastic free energy
associated with dendrimer deformation. The presence of monovalent
salt was found to relax the dendrimer deformation due to electrostatic
screening, while retaining the packing symmetry of the ribbon phase.