Phase separation of saturated micellar network and its potential applications for nanoemulsification

  title={Phase separation of saturated micellar network and its potential applications for nanoemulsification},
  author={Mihail T. Georgiev and Lyuba A. Aleksova and Peter A. Kralchevsky and Krassimir D. Danov},
  journal={Colloids and Surfaces A: Physicochemical and Engineering Aspects},
  • M. T. GeorgievLyuba A. Aleksova Krassimir D. Danov
  • Published 24 August 2020
  • Chemistry
  • Colloids and Surfaces A: Physicochemical and Engineering Aspects
5 Citations

Figures and Tables from this paper



Branched Worm-like Micelles and Their Networks

Branched worm-like micelles were found in aqueous solutions of alkylamine oxide and alkyl ethoxylate sulfate mixtures by cryo-transmission electron microscopy and formed interconnected micellar networks at high solution pH or salt concentrations.

Viscoelastic micellar solutions in nonionic fluorinated surfactant systems.

The formation and rheological behavior of a viscoelastic wormlike micellar solution in an aqueous solution of a nonionic fluorinated surfactant, perfluoroalkyl sulfonamide ethoxylate, of structure

Light-responsive vesicles based on azobenzene containing imidazolium surfactants and sodium oleate

In this work, three light responsive imidazolium surfactants containing azobenzene moiety (CmAZOCnIMB, m = 0, 2, 4 and m + n = 6), namely, 1-[2-(4-phenylazo-phenoxy)-ethyl]-7-methylimidazolium

Reptation of connected wormlike micelles

The effect of connection between giant wormlike micelles is studied. We calculate the diffusion rate, which is increased by the sliding connections. We calculate the viscosity which is weakly reduced

Microstructure and shear rheology of entangled wormlike micelles in solution

The shear rheology of a model wormlike micellar solution exhibits moderate shear thinning and curved flow velocity profiles without discontinuity (nonbanding case). The shear rheology and the flow