Some Results on $k$-Critical $P_5$-Free Graphs

A graph $G$ is $k$-vertex-critical if $G$ has chromatic number $k$ but every proper induced subgraph of $G$ has chromatic number less than $k$. The study of $k$-vertex-critical graphs for graph classes is an important topic in algorithmic graph theory because if the number of such graphs that are in a given hereditary graph class is finite, then there is a polynomial-time algorithm to decide if a graph in the class is $(k-1)$-colorable. In this paper, we prove that for every fixed integer $k\ge 1$, there are only finitely many $k$-vertex-critical ($P5$,gem)-free graphs and $(P5,\overline{P3+P2})$-free graphs. To prove the results we use a known structure theorem for ($P5$,gem)-free graphs combined with properties of $k$-vertex-critical graphs. Moreover, we characterize all $k$-vertex-critical ($P5$,gem)-free graphs and $(P5,\overline{P3+P_2})$-free graphs for $k \in {4,5}$ using a computer generation algorithm.