Random normal matrices: eigenvalue correlations near a hard wall
Abstract
We study pair correlation functions for planar Coulomb systems in the pushed phase, near a ring-shaped impenetrable wall. We assume coupling constant and that the number 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 from the hard edge. At distances much larger than , 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 as in two microscopic regimes (with either or ), as well as in three macroscopic regimes (with ). For some of these regimes, the asymptotics involve oscillatory theta functions and weighted Szeg\H{o} kernels.
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