English

Embedded minimal surfaces in $\mathbb{S}^3$ and $\mathbb{B}^3$ via equivariant eigenvalue optimization

Differential Geometry 2024-02-21 v1 Analysis of PDEs Spectral Theory

Abstract

In 1970, Lawson solved the topological realization problem for minimal surfaces in the sphere, showing that any closed orientable surface can be minimally embedded in S3\mathbb{S}^3. The analogous problem for surfaces with boundary was posed by Fraser and Li in 2014, and it has attracted much attention in recent years, stimulating the development of many new constructions for free boundary minimal surfaces. In this paper, we resolve this problem by showing that any compact orientable surface with boundary can be embedded in B3\mathbb{B}^3 as a free boundary minimal surface with area below 2π2\pi. Furthermore, we show that the number of minimal surfaces in S3\mathbb{S}^3 of prescribed topology and area below 8π8\pi, and the number of free boundary minimal surfaces in B3\mathbb{B}^3 with prescribed topology and area below 2π2\pi, grow at least linearly with the genus. This is achieved via a new method for producing minimal surfaces of prescribed topology in low-dimensional balls and spheres, based on the optimization of Laplace and Steklov eigenvalues in the presence of a discrete symmetry group. As a key ingredient, we develop new techniques for proving the existence of maximizing metrics, which can be used to resolve the existence problem in many symmetric situations and provide at least partial existence results for classical eigenvalue optimization problems.

Keywords

Cite

@article{arxiv.2402.13121,
  title  = {Embedded minimal surfaces in $\mathbb{S}^3$ and $\mathbb{B}^3$ via equivariant eigenvalue optimization},
  author = {Mikhail Karpukhin and Robert Kusner and Peter McGrath and Daniel Stern},
  journal= {arXiv preprint arXiv:2402.13121},
  year   = {2024}
}
R2 v1 2026-06-28T14:54:40.565Z