The b-Chromatic Number of Regular Graphs via The Edge Connectivity

TL;DR

This paper investigates the b-chromatic number of regular graphs, showing that for certain regular graphs without 4-cycles, the b-chromatic number equals d+1 unless the graph is super-edge-connected.

Contribution

It establishes that for regular graphs without 4-cycles, the b-chromatic number is d+1 unless the graph is super-edge-connected, extending understanding of b-colorings in regular graphs.

Findings

b-chromatic number equals d+1 for non-super-edge-connected regular graphs without 4-cycles

the Petersen graph is a unique exception in certain regular graphs

super-edge-connected graphs may have different b-chromatic properties

Abstract

\noindent The b-chromatic number of a graph $G$, denoted by $\phi(G)$, is the largest integer $k$ that $G$ admits a proper coloring by $k$ colors, such that each color class has a vertex that is adjacent to at least one vertex in each of the other color classes. El Sahili and Kouider [About b-colorings of regular graphs, Res. Rep. 1432, LRI, Univ. Orsay, France, 2006] asked whether it is true that every $d$-regular graph $G$ of girth at least 5 satisfies $\phi(G)=d+1$. Blidia, Maffray, and Zemir [On b-colorings in regular graphs, Discrete Appl. Math. 157 (2009), 1787-1793] showed that the Petersen graph provides a negative answer to this question, and then conjectured that the Petersen graph is the only exception. In this paper, we investigate a strengthened form of the question. The edge connectivity of a graph $G$, denoted by $\lambda(G)$, is the minimum cardinality of a subset $U$ of $E(G)$ such that $G\setminus U$ is either disconnected or a graph with only one vertex. A $d$-regular graph $G$ is called super-edge-connected if every minimum edge-cut is the set of all edges incident with a vertex in $G$, i.e., $\lambda(G)=d$ and every minimum edge-cut of $G$ isolates a vertex. We show that if $G$ is a $d$-regular graph that contains no 4-cycle, then $\phi(G)=d+1$ whenever $G$ is not super-edge-connected.