English

Random harmonic maps into spheres

Differential Geometry 2025-08-29 v3 Operator Algebras Probability

Abstract

Let SS be a punctured Riemann surface with Euler characteristic χ(S)<0\chi(S)<0. For any unitary representation ρ:π1(S)U(N)\rho: \pi_1(S) \to U(N), we introduce its renormalized energy and its harmonic representatives, which are equivariant harmonic maps from the universal cover of SS to the unit sphere in CN\mathbb{C}^N. Our main result is that if a sequence of unitary representations ρj\rho_j strongly converges, then their renormalized energies converge to π4χ(S)\frac{\pi}{4}|\chi(S)| and the shape of their harmonic representatives converges to a unique rescaled hyperbolic metric. Combining this statement with examples of strongly converging representations provided by random matrix theory, we derive the following applications. (1) If π1(S)\pi_1(S) is a free group, then for a random ρ:π1(S)U(N)\rho: \pi_1(S) \to U(N), the shape of its harmonic representatives concentrates around a rescaled hyperbolic metric with high probability as NN\to \infty. (2) For any closed hyperbolic surface, a finite covering admits a harmonic immersion into some Euclidean unit sphere, which is almost isometric after rescaling. (3) There are closed, branched, minimal surfaces Sj\mathfrak{S}_j in some Euclidean unit spheres such that Sj\mathfrak{S}_j Benjamini-Schramm converges to a rescaled hyperbolic plane as jj\to \infty, and the Gaussian curvature KjK_j of Sj\mathfrak{S}_j satisfies limj1Area(Sj)SjKj+8=0.\lim_{j\to \infty} \frac{1}{\mathrm{Area}(\mathfrak{S}_j)}\int_{\mathfrak{S}_j} |K_j+8|=0.

Keywords

Cite

@article{arxiv.2402.10287,
  title  = {Random harmonic maps into spheres},
  author = {Antoine Song},
  journal= {arXiv preprint arXiv:2402.10287},
  year   = {2025}
}

Comments

v2: Scope substantially broadened. Relation between harmonic maps and random matrices clarified. Title/abstract changed to reflect the update. v3: Reference added

R2 v1 2026-06-28T14:50:07.205Z