English

Section problems for configuration spaces of surfaces

Geometric Topology 2019-05-22 v3

Abstract

In this paper we give a close-to-sharp answer to the basic questions: When is there a continuous way to add a point to a configuration of nn ordered points on a surface SS of finite type so that all the points are still distinct? When this is possible, what are all the ways to do it? More precisely, let PConfn(S)_n(S) be the space of ordered nn-tuple of distinct points in SS. Let fn(S):PConfn+1(S)PConfn(S)f_n(S): \text{PConf}_{n+1}(S) \to \text{PConf}_n(S) be the map given by fn(x0,x1,,xn):=(x1,,xn)f_n(x_0,x_1,\ldots ,x_n):=(x_1,\ldots ,x_n). We classify all continuous sections of fnf_n up to homotopy by proving the following. 1. If S=R2S=\mathbb{R}^2 and n>3n>3, any section of fn(S)f_{n}(S) is either "adding a point at infinity" or "adding a point near xkx_k". (We define these two terms in Section 2.1; whether we can define "adding a point near xkx_k" or "adding a point at infinity" depends in a delicate way on properties of SS. ) 2. If S=S2S=S^2 a 22-sphere and n>4n>4, any section of fn(S)f_{n}(S) is "adding a point near xkx_k"; if S=S2S=S^2 and n=2n=2, the bundle fn(S)f_n(S) does not have a section. (We define this term in Section 3.2) 3. If S=SgS=S_g a surface of genus g>1g>1 and for n>1n>1, we give an easy proof that the bundle fn(S)f_{n}(S) does not have a section.

Keywords

Cite

@article{arxiv.1708.07921,
  title  = {Section problems for configuration spaces of surfaces},
  author = {Lei Chen},
  journal= {arXiv preprint arXiv:1708.07921},
  year   = {2019}
}

Comments

26 pages, to appear in Journal of Topology and Analysis

R2 v1 2026-06-22T21:24:06.423Z