Why can a hydrophilic polyelectrolyte precipitate and redissolve below the critical micelle concentration of an oppositely-charged surfactant ?

TL;DR

This paper presents a mean-field theoretical analysis explaining the reentrant phase transition of polyelectrolytes induced by oppositely-charged surfactants below their critical micelle concentration, highlighting electrostatic and hydrophobic effects.

Contribution

It introduces an analytical mean-field model that rationalizes the phase behavior of polyelectrolyte-surfactant systems, emphasizing the role of electrostatic adsorption and surfactant chain length.

Findings

Strong electrostatic adsorption is critical for phase transitions.

A minimum surfactant chain length is required for phase transition.

The theory explains the 'egg shape' phase diagram features.

Abstract

We theoretically study the reentrant condensation of a polyelectrolyte in the presence of an oppositely-charged surfactant,a phenomenon whose phase-transition mechanism remains under discussion. We focus on the adsorption and attraction effects of surfactant near/on polymer chains, and ignore their own non-essential mixing effects if surfactant molecules are far away from polymer chains. This approach allows us to construct a simple mean-field theory and solve it analytically, and finally rationalize the essential features (such as the "egg shape" of spinodal phase diagrams) of the reentrant condensation of a polyelectrolyte induced by diluted oppositely-charged surfactants. By theoretical analysis, we found that a strong electrostatic adsorption between the ionic monomers and surfactant ions is critical to understand the peculiar phenomenon that both the collapse and reentry transitions of polyelectrolytes can occur when the concentration of surfactant is lower than its bulk critical micelle concentration (CMC). The analytical solution of the theory indicates that a minimum coupling energy for the nonlinear hydrophobic-aggregation effect of adsorbed surfactant is essential for phase transition to occur,which explains why polyelectrolytes show phase transition only if the surfactant chain length is longer than a minimum length. The obtained results will shed light on a deep understanding of liquid-liquid phase separation in biological systems where ionic surfactant-like proteins/peptides bound to bio-polyelectrolytes play an important role.