A correlation-hole approach to the electric double layer with counter-ions only

TL;DR

This paper introduces a new self-consistent correlation-hole theory for the electric double layer with counter-ions, accurately capturing density profiles across coupling regimes and matching Monte Carlo simulations.

Contribution

A novel correlation-hole approach leading to a modified Poisson-Boltzmann equation that accurately describes the electric double layer for all coupling strengths.

Findings

Exact density profiles in weak and strong coupling limits

Profiles satisfy contact-value theorem at all couplings

Good agreement with Monte Carlo simulations for intermediate couplings

Abstract

We study a classical system of identically charged counter-ions near a planar wall carrying a uniform surface charge density. The equilibrium statistical mechanics of the system depends on a single dimensionless coupling parameter. A new self-consistent theory of the correlation-hole type is proposed which leads to a modified Poisson-Boltzmann integral equation for the density profile, convenient for analytical progress and straightforward to solve numerically. The exact density profiles are recovered in the limits of weak and strong couplings. In contrast to previous theoretical attempts of the test-charge family, the density profiles fulfill the contact-value theorem at all values of the coupling constant, and exhibit the mean-field decay at asymptotically large distances from the wall, as expected. We furthermore show that the density corrections at large couplings exhibit the proper dependence on coupling parameter and distance to the charged wall. The numerical results for intermediate values of the coupling provide accurate density profiles which are in good agreement with those obtained by Monte-Carlo simulations. The crossover to mean-field behavior at large distance is studied in detail.