Saturation numbers for Ramsey-minimal graphs

Abstract

Given graphs H1, …, Ht, a graph G is (H1, …, Ht)-Ramsey-minimal if every t-coloring of the edges of G contains a monochromatic Hi in color i for some i∈\1, …, t\, but any proper subgraph of G does not possess this property. We define R(H1, …, Ht) to be the family of (H1, …, Ht)-Ramsey-minimal graphs. A graph G is R(H1, …, Ht)-saturated if no element of R(H1, …, Ht) is a subgraph of G, but for any edge e in G, some element of R(H1, …, Ht) is a subgraph of G + e. We define sat(n, R(H1, …, Ht)) to be the minimum number of edges over all R(H1, …, Ht)-saturated graphs on n vertices. In 1987, Hanson and Toft conjectured that sat(n, R(Kk1, …, Kkt) )= (r - 2)(n - r + 2)+r - 22 for n r, where r=r(Kk1, …, Kkt) is the classical Ramsey number for complete graphs. The first non-trivial case of Hanson and Toft's conjecture for sufficiently large n was setteled in 2011, and is so far the only settled case. Motivated by Hanson and Toft's conjecture, we study the minimum number of edges over all R(K3, Tk)-saturated graphs on n vertices, where Tk is the family of all trees on k vertices. We show that for n 18, sat(n, R(K3, T4)) = 5n/2. For k 5 and n 2k + ( k/2 +1) k/2 -2, we obtain an asymptotic bound for sat(n, R(K3, Tk)).