What is a random surface?

TL;DR

This paper explores the nature of random surfaces formed by gluing triangles, their scaling limits, and their connections to various models in mathematics and physics, providing an accessible overview of a complex, interdisciplinary subject.

Contribution

It offers an informal overview of the theory of random surfaces, their scaling limits, and their deep connections to multiple fields, clarifying the concept of a random surface for a broad audience.

Findings

Convergence of random triangulated surfaces to a canonical limit

Identification of the limit with objects like the Brownian sphere and Liouville quantum gravity sphere

Extension of the concept of random surfaces to higher dimensions and complex topologies

Abstract

Given $2n$ unit equilateral triangles, there are finitely many ways to glue each edge to a partner. We obtain a random sphere-homeomorphic surface by sampling uniformly from the gluings that produce a topological sphere. As $n$ tends to infinity, these random surfaces (appropriately scaled) converge in law. The limit is a "canonical" sphere-homeomorphic random surface, much the way Brownian motion is a canonical random path. Depending on how the surface space and convergence topology are specified, the limit is the Brownian sphere, the peanosphere, the pure Liouville quantum gravity sphere, or a certain conformal field theory. All of these objects have concise definitions, and are all in some sense equivalent, but the equivalence is highly non-trivial, building on hundreds of math and physics papers over the past half century. More generally, the "continuum random surface embedded in $d$-dimensional Euclidean space" makes a kind of sense for $d \in (-\infty, 25)$ even when $d$ is not a positive integer; and this can be extended to higher genus surfaces, surfaces with boundary, and surfaces with marked points or other decoration. These constructions have deep roots in both mathematics and physics, drawing from classical graph theory, complex analysis, probability and representation theory, as well as string theory, planar statistical physics, random matrix theory and a simple model for two-dimensional quantum gravity. We present here an informal, colloquium-level overview of the subject, which we hope will be accessible to both newcomers and experts. We aim to answer, as cleanly as possible, the fundamental question. What is a random surface?