Graph coloring with no large monochromatic components
Abstract
For a graph G and an integer t we let mcct(G) be the smallest m such that there exists a coloring of the vertices of G by t colors with no monochromatic connected subgraph having more than m vertices. Let F be any nontrivial minor-closed family of graphs. We show that 2(G) = O(n2/3) for any n-vertex graph G ∈ F. This bound is asymptotically optimal and it is attained for planar graphs. More generally, for every such F and every fixed t we show that mcct(G)=O(n2/(t+1)). On the other hand we have examples of graphs G with no Kt+3 minor and with mcct(G)=(n2/(2t-1)). It is also interesting to consider graphs of bounded degrees. Haxell, Szabo, and Tardos proved 2(G) ≤ 20000 for every graph G of maximum degree 5. We show that there are n-vertex 7-regular graphs G with 2(G)=(n), and more sharply, for every ε>0 there exists cε>0 and n-vertex graphs of maximum degree 7, average degree at most 6+ε for all subgraphs, and with mcc2(G) c n. For 6-regular graphs it is known only that the maximum order of magnitude of 2 is between n and n. We also offer a Ramsey-theoretic perspective of the quantity t(G).
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