Charged Membranes: Poisson-Boltzmann theory, DLVO paradigm and beyond

TL;DR

This chapter reviews the electrostatic properties of charged membranes using Poisson-Boltzmann theory, analyzing boundary conditions, interactions, and the DLVO paradigm, highlighting recent modifications and limitations of the models.

Contribution

It provides a comprehensive analysis of membrane electrostatics, including boundary condition effects, charge regulation, and the integration of van der Waals interactions within the DLVO framework.

Findings

Different solutions of the PB equation for single membranes.

Analytical crossover from repulsion to attraction between membranes.

Inclusion of van der Waals forces via Lifshitz theory.

Abstract

In this chapter we review the electrostatic properties of charged membranes in aqueous solutions, with or without added salt, employing simple physical models. The equilibrium ionic profiles close to the membrane are governed by the well-known Poisson-Boltzmann (PB) equation. We analyze the effect of different boundary conditions, imposed by the membrane, on the ionic profiles and the corresponding osmotic pressure. The discussion is separated into the single membrane case and that of two interacting membranes. For one membrane setup, we show the different solutions of the PB equation and discuss the interplay between constant-charge and constant-potential boundary conditions. A modification of the PB theory is presented to treat the extremely high counter-ion concentration in the vicinity of a charge membrane. For two equally-charged membranes, we analyze the different pressure regimes for the constant-charge boundary condition, and discuss the difference in the osmotic pressure for various boundary conditions. The non-equal charged membranes is reviewed as well, and the crossover from repulsion to attraction is calculated analytically. We then examine the charge-regulation boundary condition and discuss its effects on the ionic profiles and the osmotic pressure for two equally-charged membranes. In the last section, we briefly review the van der Waals (vdW) interactions and their effect on the free energy between two planar membranes. We explain the simple Hamaker pair-wise summation procedure, and introduce the more rigorous Lifshitz theory. The latter is a key ingredient in the DLVO theory, which combines repulsive electrostatic with attractive vdW interactions, and offers a simple explanation for colloidal or membrane stability. Finally, the chapter ends by a short account of the limitations of the approximations inherent in the PB theory.