| Popis: |
Strengthened notions of a matching $M$ of a graph $G$ have been considered, requiring that the matching $M$ has some properties with respect to the subgraph $G_M$ of $G$ induced by the vertices covered by $M$: If $M$ is the unique perfect matching of $G_M$, then $M$ is a uniquely restricted matching of $G$; if all the edges of $M$ are pendant edges of $G_M$, then $M$ is a semistrong matching of $G$; if all the vertices of $G_M$ are pendant, then $M$ is an induced matching of $G$. Strengthened notions of edge coloring and of the chromatic index follow. In this paper, we consider the maximum semistrong chromatic index of planar graphs with given maximum degree $\Delta$. We prove that graphs with maximum average degree less than ${14}/{5}$ have semistrong chromatic index (hence uniquely restricted chromatic index) at most $2\Delta+4$, and we reduce the bound to $2\Delta+2$ if the maximum average degree is less than ${8}/{3}$. These cases cover, in particular, the cases of planar graphs with girth at least 7 (resp. at least 8). Our result makes some progress on the conjecture of Lu\v{z}ar, Mockov\v{c}iakov\'a and Sot\'ak [J. Graph Theory 105 (2024) 612--632], which asserts that every planar graph $G$ has a semistrong edge coloring with $2\Delta+C$ colors, for some universal constant $C$. (Note that such a conjecture would fail for strong edge coloring as there exist graphs with arbitrarily large maximum degree that are not strongly $(4\Delta-5)$-edge-colorable.) We conjecture that the upper bound for both the uniquely restricted chromatic index and the semistrong chromatic index of planar graphs with maximum degree $\Delta$ is $2\Delta+4$, and provide an example of a planar graph achieving this bound. |
