Random punctured hyperbolic surfaces & the Brownian sphere

Abstract

We consider random genus-0 hyperbolic surfaces Sn with n + 1 punctures, sampled according to the Weil-Petersson measure. We show that, after rescaling the metric by n-1/4, the surface Sn converges in distribution to the Brownian sphere - a random compact metric space homeomorphic to the 2-sphere, exhibiting fractal geometry and appearing as a universal scaling limit in various models of random planar maps. Without rescaling the metric, we establish a local Benjamini--Schramm convergence of Sn to a random infinite-volume hyperbolic surface with countably many punctures, homeomorphic to R2 Z2. Our proofs mirror techniques from the theory of random planar maps. In particular, we develop an encoding of punctured hyperbolic surfaces via a family of plane trees with continuous labels, akin to Schaeffer's bijection. This encoding stems from the Epstein-Penner decomposition and, through a series of transformations, reduces to a model of single-type Galton--Watson trees, enabling the application of known invariance principles.