English

Complexes of graph homomorphisms

Combinatorics 2007-05-23 v4 Algebraic Topology

Abstract

Hom(G,H)Hom(G,H) is a polyhedral complex defined for any two undirected graphs GG and HH. This construction was introduced by Lov\'asz to give lower bounds for chromatic numbers of graphs. In this paper we initiate the study of the topological properties of this class of complexes. We prove that Hom(Km,Kn)Hom(K_m,K_n) is homotopy equivalent to a wedge of (nm)(n-m)-dimensional spheres, and provide an enumeration formula for the number of the spheres. As a corollary we prove that if for some graph GG, and integers m2m\geq 2 and k1k\geq -1, we have ϖ1k(\thom(Km,G))0\varpi_1^k(\thom(K_m,G))\neq 0, then χ(G)k+m\chi(G)\geq k+m; here Z2Z_2-action is induced by the swapping of two vertices in KmK_m, and ϖ1\varpi_1 is the first Stiefel-Whitney class corresponding to this action. Furthermore, we prove that a fold in the first argument of Hom(G,H)Hom(G,H) induces a homotopy equivalence. It then follows that Hom(F,Kn)Hom(F,K_n) is homotopy equivalent to a direct product of (n2)(n-2)-dimensional spheres, while Hom(Fˉ,Kn)Hom(\bar{F},K_n) is homotopy equivalent to a wedge of spheres, where FF is an arbitrary forest and Fˉ\bar{F} is its complement.

Keywords

Cite

@article{arxiv.math/0310056,
  title  = {Complexes of graph homomorphisms},
  author = {Eric Babson and Dmitry N. Kozlov},
  journal= {arXiv preprint arXiv:math/0310056},
  year   = {2007}
}

Comments

This is the first part of the series of papers containing the complete proofs of the results announced in "Topological obstructions to graph colorings". This is the final version which is to appear in Israel J. Math., it has an updated list of references and new remarks on latest developments