Equilibrium Dynamics of Microemulsion and Sponge Phases
arXiv:cond-mat/9408001 · doi:10.1051/jp2:1994205
Abstract
The dynamic structure factor $G({\bf k},Ï)$ is studied in a time-dependent Ginzburg-Landau model for microemulsion and sponge phases in thermal equilibrium by field-theoretic perturbation methods. In bulk contrast, we find that for sufficiently small viscosity $η$, the structure factor develops a peak at non-zero frequency $Ï$, for fixed wavenumber $k$ with $k_0 < k {< \atop \sim} q$. Here, $2Ï/q$ is the typical domain size of oil- and water-regions in a microemulsion, and $k_0 \sim ηq^2$. This implies that the intermediate scattering function, $G({\bf k}, t)$, {\it oscillates} in time. We give a simple explanation, based on the Navier-Stokes equation, for these temporal oscillations by considering the flow through a tube of radius $R \simeq Ï/q$, with a radius-dependent tension.
24 pages, LaTex, 11 Figures on request; J. Phys. II France 4 (1994) to be published