On the sizes of k-edge-maximal r-uniform hypergraphs

Abstract

Let H=(V,E) be a hypergraph, where V is a set of vertices and E is a set of non-empty subsets of V called edges. If all edges of H have the same cardinality r, then H is a r-uniform hypergraph; if E consists of all r-subsets of V, then H is a complete r-uniform hypergraph, denoted by Knr, where n=|V|. A hypergraph H'=(V',E') is called a subhypergraph of H=(V,E) if V'⊂eq V and E'⊂eq E. A r-uniform hypergraph H=(V,E) is k-edge-maximal if every subhypergraph of H has edge-connectivity at most k, but for any edge e∈ E(Knr) E(H), H+e contains at least one subhypergraph with edge-connectivity at least k+1. Let k and r be integers with k≥2 and r≥2, and let t=t(k,r) be the largest integer such that (t-1r-1)≤ k. That is, t is the integer satisfies (t-1r-1)≤ k<(tr-1). We prove that if H is a r-uniform k-edge-maximal hypergraph such that n=|V(H)|≥ t, then (i) |E(H)|≤ (tr)+(n-t)k, and this bound is best possible; (ii) |E(H)|≥ (n-1)k -((t-1)k-(tr))nt, and this bound is best possible. This extends former results in [8] and [6].