Abstract
The dichromatic number $\overrightarrow{\chi}(D)$ of a digraph $D$ is the minimum number of colors needed to color the vertices of $D$ such that each color class induces an acyclic subdigraph of $D$. A digraph $D$ is $k$-critical if $\overrightarrow{\chi}(D) = k$ but $\overrightarrow{\chi}(D') < k$ for all proper subdigraphs $D'$ of $D$. We examine methods for creating infinite families of critical digraphs, the Dirac join and the directed and bidirected Hajós join. We prove that a digraph $D$ has dichromatic number at least $k$ if and only if it contains a subdigraph that can be obtained from bidirected complete graphs on $k$ vertices by directed Hajós joins and identifying non-adjacent vertices. Building upon that, we show that a digraph $D$ has dichromatic number at least $k$ if and only if it can be constructed from bidirected $K_k$'s by using directed and bidirected Hajós joins and identifying non-adjacent vertices (so called Ore joins), thereby transferring a well-known result of Urquhart to digraphs. Finally, we prove a Gallai-type theorem that characterizes the structure of the low vertex subdigraph of a critical digraph, that is, the subdigraph, which is induced by the vertices that have in-degree $k-1$ and out-degree $k-1$ in $D$.
Highlights
Recall that the chromatic number χ(G) of a graph G is the minimum number of colors needed to color the vertices of G so that each color class induces an edgeless subgraph of G
A graph G is k-critical if χ(G) = k but χ(G′) < k for each proper subgraph G′ of G
We study the digraph analogue of two well-known methods for creating infinite families of critical graphs, the so-called Dirac join and the directed and bidirected Hajós join
Summary
Recall that the chromatic number χ(G) of a graph G is the minimum number of colors needed to color the vertices of G so that each color class induces an edgeless subgraph of G. K} the color class φ−1(α) = {v ∈ V (D) | φ(v) = α} induces an acyclic subdigraph of D, i.e. a subdigraph that does not contain any directed cycles. It is easy to see that Crit(0) = {∅}, Crit(1) = {K1}, and Crit(2) consists of all directed cycles It is not even known which digraphs Crit(3) consists of; unlike in the undirected case, where it follows from König’s characterization of bipartite graphs [19] that Crit(3) coincides with the class of all odd cycles. We study the digraph analogue of two well-known methods for creating infinite families of critical graphs, the so-called Dirac join and the directed and bidirected Hajós join.
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