A Viscoelastic model of phase separation

TL;DR

This paper introduces a comprehensive viscoelastic model for phase separation in isotropic materials, emphasizing the role of bulk and shear relaxation moduli, and explains the formation of sponge-like structures.

Contribution

It presents a novel, general viscoelastic phase separation model that incorporates bulk relaxation effects, unifying various types of phase separation phenomena.

Findings

Bulk relaxation modulus influences phase separation dynamics.

The model explains sponge structure formation.

It unifies solid and fluid phase separation models.

Abstract

We show here a general model of phase separation in isotropic condensed matter, namely, a viscoelastic model. We propose that the bulk mechanical relaxation modulus that has so far been ignored in previous theories plays an important role in viscoelastic phase separation in addition to the shear relaxation modulus. In polymer solutions, for example, attractive interactions between polymers under a poor-solvent condition likely cause the transient gellike behavior, which makes both bulk and shear modes active. Although such attractive interactions between molecules of the same component exist universally in the two-phase region of a mixture, the stress arising from attractive interactions is asymmetrically divided between the components only in dynamically asymmetric mixtures such as polymer solutions and colloidal suspensions. Thus, the interaction network between the slower components, which can store the elastic energy against its deformation through bulk and shear moduli, is formed. It is the bulk relaxation modulus associated with this interaction network that is primarily responsible for the appearance of the sponge structure peculiar to viscoelastic phase separation and the phase inversion. We demonstrate that a viscoelastic model of phase separation including this new effect is a general model that can describe all types of isotropic phase separation including solid and fluid models as its special cases without any exception, if there is no coupling with additional order parameter. The physical origin of volume shrinking behavior during viscoelastic phase separation and the universality of the resulting spongelike structure are also discussed.