English

Weak saturation in graphs: a combinatorial approach

Combinatorics 2023-05-26 v2

Abstract

The weak saturation number wsat(n,F)\mathrm{wsat}(n,F) is the minimum number of edges in a graph on nn vertices such that all the missing edges can be activated sequentially so that each new edge creates a copy of FF. A usual approach to prove a lower bound for the weak saturation number is algebraic: if it is possible to embed edges of KnK_n in a vector space in a certain way (depending on FF), then the dimension of the subspace spanned by the images of the edges of KnK_n is a lower bound for the weak saturation number. In this paper, we present a new combinatorial approach to prove lower bounds for weak saturation numbers that allows to establish worst-case tight (up to constant additive terms) general lower bounds as well as to get exact values of the weak saturation numbers for certain graph families. It is known (Alon, 1985) that, for every FF, there exists cFc_F such that wsat(n,F)=cFn(1+o(1))\mathrm{wsat}(n,F)=c_Fn(1+o(1)). Our lower bounds imply that all values in the interval [δ21δ+1,δ1]\left[\frac{\delta}{2}-\frac{1}{\delta+1},\delta-1\right] with step size 1δ+1\frac{1}{\delta+1} are achievable by cFc_F (while any value outside this interval is not achievable).

Keywords

Cite

@article{arxiv.2305.11043,
  title  = {Weak saturation in graphs: a combinatorial approach},
  author = {Nikolai Terekhov and Maksim Zhukovskii},
  journal= {arXiv preprint arXiv:2305.11043},
  year   = {2023}
}
R2 v1 2026-06-28T10:38:20.172Z