English

Random normal matrices: eigenvalue correlations near a hard wall

Mathematical Physics 2024-07-29 v2 math.MP Probability

Abstract

We study pair correlation functions for planar Coulomb systems in the pushed phase, near a ring-shaped impenetrable wall. We assume coupling constant Γ=2\Gamma=2 and that the number nn of particles is large. We find that the correlation functions decay slowly along the edges of the wall, in a narrow interface stretching a distance of order 1/n1/n from the hard edge. At distances much larger than 1/n1/\sqrt{n}, the effect of the hard wall is negligible and pair correlation functions decay very quickly, and in between sits an interpolating interface that we call the ``semi-hard edge''. More precisely, we provide asymptotics for the correlation kernel Kn(z,w)K_{n}(z,w) as nn\to\infty in two microscopic regimes (with either zw=O(1/n)|z-w| = \mathcal{O} (1/\sqrt{n}) or zw=O(1/n)|z-w| = \mathcal{O} (1/n)), as well as in three macroscopic regimes (with zw1|z-w| \asymp 1). For some of these regimes, the asymptotics involve oscillatory theta functions and weighted Szeg\H{o} kernels.

Keywords

Cite

@article{arxiv.2306.14166,
  title  = {Random normal matrices: eigenvalue correlations near a hard wall},
  author = {Yacin Ameur and Christophe Charlier and Joakim Cronvall},
  journal= {arXiv preprint arXiv:2306.14166},
  year   = {2024}
}

Comments

46 pages, 5 figures. Our results are summarized in Figure 2

R2 v1 2026-06-28T11:13:44.792Z