On the chromatic edge stability index of graphs

TL;DR

This paper studies the chromatic edge stability index of graphs, classifies extremal cases, and explores computational complexity and structural properties of mitigating sets.

Contribution

It classifies graphs with extremal and near-extremal stability index values, characterizes regular graphs with index 1, and proposes a conjecture on mitigating sets being matchings.

Findings

Graphs with maximum stability index are classified.

Regular graphs with stability index 1 are exactly odd cycles and K2.

Verifying stability index 1 is NP-hard.

Abstract

Given a non-trivial graph $G$, the minimum cardinality of a set of edges $F$ in $G$ such that $\chi'(G \setminus F)<\chi'(G)$ is called the chromatic edge stability index of $G$, denoted by $es_{\chi'}(G)$, and such a (smallest) set $F$ is called a (minimum) mitigating set. While $1\le es_{\chi'}(G)\le \lfloor n/2\rfloor$ holds for any graph $G$, we investigate the graphs with extremal and near-extremal values of $es_{\chi'}(G)$. The graphs $G$ with $es_{\chi'}(G)=\lfloor n/2\rfloor$ are classified, and the graphs $G$ with $es_{\chi'}(G)=\lfloor n/2\rfloor-1$ and $\chi'(G)=\Delta(G)+1$ are characterized. We establish that the odd cycles and $K_2$ are exactly the regular connected graphs with the chromatic edge stability index $1$; on the other hand, we prove that it is NP-hard to verify whether a graph $G$ has $es_{\chi'}(G)=1$. We also prove that every minimum mitigating set of an $r$-regular graph $G$, where $r\ne 4$, with $es_{\chi'}(G)=2$ is a matching. Furthermore, we propose a conjecture that for every graph $G$ there exists a minimum mitigating set, which is a matching, and prove that the conjecture holds for graphs $G$ with $es_{\chi'}(G)\in\{1,2,\lfloor n/2\rfloor-1,\lfloor n/2\rfloor\}$, and for bipartite graphs.