Electrostatic Correlation Augmented Self-Consistent Field Theory and Its Application to Polyelectrolyte Brushes

TL;DR

This paper introduces a new electrostatic correlation-augmented self-consistent field theory for polymers, revealing how ion correlations influence polyelectrolyte brush behavior, including collapse, reexpansion, and microphase separation, aligning well with experimental data.

Contribution

The authors develop a systematic theory incorporating electrostatic fluctuations into polymer self-consistent field models, specifically applied to polyelectrolyte brushes, revealing new insights into ion correlation effects.

Findings

Ion correlations cause non-monotonic brush height changes.

Strong ion correlations can induce microphase separation.

The theory aligns well with experimental observations.

Abstract

Modeling ion correlations in inhomogeneous polymers and soft matters with spatially varying ionic strength or dielectric permittivity remains a great challenge. Here, we develop a new theory which systematically incorporates electrostatic fluctuations into the self-consistent field theory for polymers. Applied to polyelectrolyte brushes, the theory predicts that ion correlations induce non-monotonic change of the brush height: collapse followed by reexpansion. The scaling analysis elucidates the competition between the repulsive osmotic pressure due to translational entropy and the attraction induced by ion correlations. We also clarify the absence of causal relationship between the brush collapse-reexpansion and the inversion of the surface electrostatic potential. Furthermore, strong ion correlations can trigger microphase separation, either in the lateral direction as pinned micelles or in the normal direction as oscillatory layers. Our theoretical predictions are in good agreement with the experimental results reported in the literature.