Berge tight cycles of all lengths in hypergraphs

Abstract

Given a set R of positive integers, an R-graph H = (V, E) is a hypergraph where the cardinality of each hyperedge belongs to R. If R = \r\, we sometimes refer to the hypergraph as an r-graph rather than an R-graph. For a set S ⊂eq V, let dH(S) denote the number of hyperedges of H containing S. Given a nonnegative integer s, the minimum s-degree δs(H) is the minimum of dH(S) over all s-vertex subsets S of V. Let r and t be positive integers with r < t. We denote by Ctr the t-vertex r-uniform tight cycle, which is an r-graph with at least three hyperedges whose vertices admit a cyclic ordering such that every r consecutive vertices form a hyperedge. In particular, Ct2 is the classical cycle Ct in 2-graphs. For hypergraphs F and H, we say that H is a Berge-F if there exist an injection f V(F) V(H) and a bijection g E(F) E(H) such that \f(v): v ∈ e\ ⊂eq g(e) for all e ∈ E(F). Lu and Wang [Discrete Math. 344 (2021), 112462] proved that every [3]-graph H on n ≥ 6 vertices with δ2(H) ≥ 1 contains a Berge-Ct for all 3 ≤ t ≤ n. In this paper, we prove that for any positive integer r and any set R ⊂eq [k] with k ≥ 2, there exists an integer n0 = n0(k,r) such that every R-graph H on n ≥ n0 vertices with δr(H) ≥ 1 contains a Berge-Ctr for all r+1 ≤ t ≤ n. In particular, when k = 4 and r = 3, we show that every [4]-graph H on n ≥ 9 vertices with δ3(H) ≥ 1 contains a Berge-Ct3 for all 4 ≤ t ≤ n. We also characterize all the counterexamples when 4 ≤ n ≤ 8.