Edge-colored 3-uniform hypergraphs without rainbow paths of length 3 and its applications to Ramsey theory

Abstract

Motivated by Ramsey theory problems, we consider edge-colorings of 3-uniform hypergraphs that contain no rainbow paths of length 3. There are three 3-uniform paths of length 3: the tight path T=\v1v2v3, v2v3v4, v3v4v5\, the messy path M=\v1v2v3, v2v3v4, v4v5v6\ and the loose path L=\v1v2v3, v3v4v5, v5v6v7\. In this paper, we characterize the structures of edge-colored complete 3-uniform hypergraph Kn(3) without rainbow T, M and L, respectively. This generalizes a result of Thomason-Wagner on edge-colored complete graph Kn without rainbow paths of length 3. We also obtain a multipartite generalization of these results. As applications, we obtain several Ramsey-type results. Given two 3-uniform hypergraphs H and G, the constrained Ramsey number f(H,G) is defined as the minimum integer n such that, in every edge-coloring of K(3)n with any number of colors, there is either a monochromatic copy of H or a rainbow copy of G. For G∈ \T, M, L\ and infinitely many 3-uniform hypergraphs H, we reduce f(H, G) to the 2-colored Ramsey number R2(H) of H, that is, f(H, G)=R2(H). Given a 3-uniform hypergraph G and an integer n≥ |V(G)|, the anti-Ramsey number ar(n, G) is the minimum integer k such that, in every edge-coloring of K(3)n with at least k colors, there is a rainbow copy of G. We show that ar(n, T)=n3+2 for n≥ 5, ar(n, M)=3 for n≥ 7, and ar(n, L)=n for n≥ 7. Our newly obtained Ramsey-type results extend results of Gy\'arf\'as-Lehel-Schelp and Liu on constrained Ramsey numbers, and improve a result of Tang-Li-Yan on anti-Ramsey numbers.

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