Crowns in linear 3-graphs

Abstract

A linear 3-graph, H = (V, E), is a set, V, of vertices together with a set, E, of 3-element subsets of V, called edges, so that any two distinct edges intersect in at most one vertex. The linear Tur\'an number, ex(n,F), is the maximum number of edges in a linear 3-graph H with n vertices containing no copy of F. We focus here on the crown, C, which consists of three pairwise disjoint edges (jewels) and a fourth edge (base) which intersects all of the jewels. Our main result is that every linear 3-graph with minimum degree at least 4 contains a crown. This is not true if 4 is replaced by 3. In fact the known bounds of the Tur\'an number are \[ 6 n - 34 ≤ ex(n, C) ≤ 2n, \] and in the construction providing the lower bound all but three vertices have degree 3. We conjecture that ex(n, C) 3n2 but even if this were known it would not imply our main result. Our second result is a step towards a possible proof of ex(n,C) ≤ 3n2 (i.e., determining it within a constant error). We show that a minimal counterexample to this statement must contain certain configurations with 9 edges and we conjecture that all of them lead to contradiction.