English

Exceptionally strong double-layer barriers generated by polyampholyte salt

Soft Condensed Matter 2025-08-05 v1

Abstract

Experiments using the Surface Force Apparatus (SFA) have found anomalously long-ranged interactions between charged surfaces in concentrated salt solutions. Ion clustering have been suggested as a possible origin of this behaviour. In this work, we demonstrate that if such stable clusters indeed form, they are able to induce remarkably strong free energy barriers, under conditions where a corresponding solution of simple salt provide negligible forces. Our cluster model is based on connected ions producing a polyampholyte salt, containing a symmetric mixture of monovalent cationic and anionic polyampholytes. Ion distributions and surface interactions are evaluated utilising statistical-mechanical (classical) polymer Density Functional Theory, cDFT. In the Supporting Information, we briefly investigate a range of different polymer architectures (connectivities), but in the main part of the work a polyampholyte ion is modelled as a linear chain with alternating charges, in which the ends carry an identical charge (hence, a monovalent net charge). These salts are able to generate repulsions, between similarly charged surfaces, of a remarkable strength - exceeding those from simple salts by orders of magnitude. The underlying mechanism for this is the formation of brush-like layers at the surfaces, i.e. the repulsion is strongly related to excluded volume effects, in a manner similar to the interaction between surfaces carrying grafted polymers. We believe our results are relevant not only to possible mechanisms underlying anomalously long-ranged underscreening in concentrated simple salt solutions, but also for the potential use of synthesised polyampholyte salt as extremely efficient stabilisers of colloidal dispersions.

Keywords

Cite

@article{arxiv.2412.04228,
  title  = {Exceptionally strong double-layer barriers generated by polyampholyte salt},
  author = {David Ribar and Clifford E. Woodward and Jan Forsman},
  journal= {arXiv preprint arXiv:2412.04228},
  year   = {2025}
}
R2 v1 2026-06-28T20:24:19.471Z