Abstract
We show that for $n \geq 3, n\ne 5$, in any partition of $\mathcal{P}(n)$, the set of all subsets of $[n]=\{1,2,\dots,n\}$, into $2^{n-2}-1$ parts, some part must contain a triangle — three different subsets $A,B,C\subseteq [n]$ such that $A\cap B,A\cap C,B\cap C$ have distinct representatives. This is sharp, since by placing two complementary pairs of sets into each partition class, we have a partition into $2^{n-2}$ triangle-free parts. We also address a more general Ramsey-type problem: for a given graph $G$, find (estimate) $f(n,G)$, the smallest number of colors needed for a coloring of $\mathcal{P}(n)$, such that no color class contains a Berge-$G$ subhypergraph. We give an upper bound for $f(n,G)$ for any connected graph $G$ which is asymptotically sharp when $G$ is a cycle, path, or star. Additional bounds are given when $G$ is a $4$-cycle and when $G$ is a claw.
Highlights
A hypergraph H = (V, F ) is called Berge-G if G = (V, E) is a graph and there exists a bijection g : E(G) → E(H) such that for e ∈ E(G) we have e ⊆ g(e)
Berge-G hypergraphs were defined by Gerbner and Palmer [4] to extend the notion of paths and cycles in hypergraphs introduced by Berge in [3]
A Berge-C3 hypergraph consists of three subsets A, B, C ⊆ [n] such that A ∩ B, A ∩ C, B ∩ C have distinct representatives
Summary
In any of the three cases of the lemma, we first want to find three pairwise intersecting sets. Let A, B, C ∈ M ∪ L be three distinct pairwise intersecting sets, in any case, and suppose they do not form a triangle. By Hall’s theorem as applied to distinct representatives, there are only a few cases where they may not form a triangle.
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