Dipole Formation in the Two-Component Plasma

TL;DR

This paper analyzes the two-dimensional two-component plasma, demonstrating a phase transition at 2 from free charges to dipole pairs as the temperature increases, using a regularized interaction and energy estimates.

Contribution

It introduces a regularization and energy estimates to rigorously describe dipole formation and phase transition at 2 in the Coulomb gas.

Findings

Charges form small neutral dipoles for 2 2 at high temperature

The model exhibits a phase transition at 2 from free charges to dipoles

Provides estimates on the size of linear statistics in the system

Abstract

We consider the two-dimensional two-component plasma, or Coulomb gas, consisting of $N$ positive and $N$ negative charges with logarithmic interaction. We introduce a suitable regularization of the interaction by smearing the charges over a small length scale $\lambda$, which allows us to give meaning to the system in the continuum at any temperature. We provide an expansion of the free energy in terms of the inverse temperature $\beta$, as $N \to \infty$ and $\lambda \to 0$. Doing so allows us to show that, for $\beta \geq 2$, the charges (for the most part) pair into neutral dipoles of very small size as $\lambda \to 0$. This complements the prior work of Lebl\'e, Zeitouni, and the second author, which proved that this does not happen for $\beta < 2$, thereby implying a transition at $\beta = 2$ from free charges to dipole pairs. Moreover, we obtain an estimate on the size of linear statistics. The description in terms of dipoles is made via a decomposition into nearest-neighbor graphs of the point configurations, \`a la Gunson-Panta. This is combined with new energy estimates obtained via an electric reformulation of the interaction energy and a ball-growth method, which are expressed in terms of the nearest-neighbor graph distances only. In this way, the model is compared to a reduced nearest-neighbor interaction model, by showing the relative smallness of the dipole-dipole interactions.