English

(Treewidth, Clique)-Boundedness and Poly-logarithmic Tree-Independence

Combinatorics 2026-05-07 v4

Abstract

An independent set in a graph GG is a set of pairwise non-adjacent vertices. A tree decomposition of GG is a pair (T,χ)(T, \chi) where TT is a tree and χ:V(T)2V(G)\chi : V(T) \rightarrow 2^{V(G)} is a function satisfying the following two axioms: for every edge uvV(G)uv \in V(G) there is a xV(T)x \in V(T) such that {u,v}χ(x)\{u,v\} \subseteq \chi(x), and for every vertex uV(G)u \in V(G) the set {xV(T) : uχ(X)}\{x \in V(T) ~:~ u \in \chi(X)\} induces a non-empty and connected subtree of TT. The sets χ(x)\chi(x) for xV(T)x \in V(T) are called the bags of the tree decomposition. The tree-independence number of GG is the minimum taken over all tree decompositions of GG of the maximum size of an independent set of the graph induced by a bag of the tree decomposition. The study of graph classes with bounded tree-independence number has attracted much attention in recent years, in part due its improtant algorithmic implications. A conjecture of Dallard, Milani\v{c} and \v{S}torgel, connecting tree-independence number to the classical notion of treewidth, was one of the motivating problems in the area. This conjecture was recently disproved, but here we prove a slight variant of it, that retains much of the algorithmic significance. As part of the proof we introduce the notion of independence-containers, which can be viewed as a generalization of the set of all maximal cliques of a graph, and is of independent interest.

Keywords

Cite

@article{arxiv.2510.15074,
  title  = {(Treewidth, Clique)-Boundedness and Poly-logarithmic Tree-Independence},
  author = {Maria Chudnovsky and Ajaykrishnan E S and Daniel Lokshtanov},
  journal= {arXiv preprint arXiv:2510.15074},
  year   = {2026}
}
R2 v1 2026-07-01T06:42:05.942Z