English

Counting curves on surfaces

Geometric Topology 2016-02-01 v2 Mathematical Physics Combinatorics math.MP

Abstract

In this paper we consider an elementary, and largely unexplored, combinatorial problem in low-dimensional topology. Consider a real 2-dimensional compact surface SS, and fix a number of points FF on its boundary. We ask: how many configurations of disjoint arcs are there on SS whose boundary is FF? We find that this enumerative problem, counting curves on surfaces, has a rich structure. For instance, we show that the curve counts obey an effective recursion, in the general framework of topological recursion. Moreover, they exhibit quasi-polynomial behaviour. This "elementary curve-counting" is in fact related to a more advanced notion of "curve-counting" from algebraic geometry or symplectic geometry. The asymptotics of this enumerative problem are closely related to the asymptotics of volumes of moduli spaces of curves, and the quasi-polynomials governing the enumerative problem encode intersection numbers on moduli spaces. Furthermore, among several other results, we show that generating functions and differential forms for these curve counts exhibit structure that is reminiscent of the mathematical physics of free energies, partition functions, topological recursion, and quantum curves.

Keywords

Cite

@article{arxiv.1512.08853,
  title  = {Counting curves on surfaces},
  author = {Norman Do and Musashi A. Koyama and Daniel V. Mathews},
  journal= {arXiv preprint arXiv:1512.08853},
  year   = {2016}
}

Comments

87 pages, 11 figures. v2: Included references to previous work in the literature

R2 v1 2026-06-22T12:19:50.819Z