English

Edge-decomposing graphs into coprime forests

Combinatorics 2018-03-13 v1 Discrete Mathematics

Abstract

The Barat-Thomassen conjecture, recently proved in [Bensmail et al.: A proof of the Barat-Thomassen conjecture. J. Combin. Theory Ser. B, 124:39-55, 2017.], asserts that for every tree T, there is a constant cTc_T such that every cTc_T-edge connected graph G with number of edges (size) divisible by the size of T admits an edge partition into copies of T (a T-decomposition). In this paper, we investigate in which case the connectivity requirement can be dropped to a minimum degree condition. For instance, it was shown in [Bensmail et al.: Edge-partitioning a graph into paths: beyond the Barat-Thomassen conjecture. arXiv:1507.08208] that when T is a path with k edges, there is a constant dkd_k such that every 24-edge connected graph G with size divisible by k and minimum degree dkd_k has a T-decomposition. We show in this paper that when F is a coprime forest (the sizes of its components being a coprime set of integers), any graph G with sufficiently large minimum degree has an F-decomposition provided that the size of F divides the size of G (no connectivity is required). A natural conjecture asked in [Bensmail et al.: Edge-partitioning a graph into paths: beyond the Barat-Thomassen conjecture. arXiv:1507.08208] asserts that for a fixed tree T, any graph G of size divisible by the size of T with sufficiently high minimum degree has a T-decomposition, provided that G is sufficiently highly connected in terms of the maximal degree of T. The case of maximum degree 2 is answered by paths. We provide a counterexample to this conjecture in the case of maximum degree 3.

Keywords

Cite

@article{arxiv.1803.03704,
  title  = {Edge-decomposing graphs into coprime forests},
  author = {Tereza Klimošová and Stéphan Thomassé},
  journal= {arXiv preprint arXiv:1803.03704},
  year   = {2018}
}
R2 v1 2026-06-23T00:48:12.351Z