A formula for the edge density $\sqrt{n}$-correction for two-dimensional Coulomb systems (2510.16945v1)

Abstract: In connection with recent work on smallest gaps, C.~Charlier proves that the 1-point function of a suitable planar Coulomb system ${z_j}_1^n$, in the determinantal case with respect to an external potential $Q(z)$, admits the expansion, as $n\to\infty$, $$R_n\bigg(z_0+\frac t {\sqrt{2n\partial\bar{\partial} Q(z_0)}}\nu(z_0)\bigg)=n\partial\bar{\partial} Q(z_0)\frac {\operatorname{erfc} t}2+\sqrt{n\partial\bar{\partial} Q(z_0)}\,C(z_0;t)+\mathcal{O}(\log^3 n).$$ Here $t$ is a real parameter, $z_0$ is a regular boundary point of the (connected) Coulomb droplet and $\nu(z_0)$ is the outwards unit normal; the coefficient $C(z_0;t)$ has an apriori structure depending on a number of parameters. In this note we identify the parameters and obtain a formula for $C(z_0;t)$ in potential theoretic and geometric terms. Our formula holds for a large class of potentials such that the droplet is connected with smooth boundary. Our derivation uses the well known expectation of fluctuations formula.