Minimum Degrees of Minimal Ramsey Graphs for Almost-Cliques

Abstract

For graphs F and H, we say F is Ramsey for H if every 2-coloring of the edges of F contains a monochromatic copy of H. The graph F is Ramsey H-minimal if F is Ramsey for H and there is no proper subgraph F' of F so that F' is Ramsey for H. Burr, Erdos, and Lovasz defined s(H) to be the minimum degree of F over all Ramsey H-minimal graphs F. Define Ht,d to be a graph on t+1 vertices consisting of a complete graph on t vertices and one additional vertex of degree d. We show that s(Ht,d)=d2 for all values 1<d t; it was previously known that s(Ht,1)=t-1, so it is surprising that s(Ht,2)=4 is much smaller. We also make some further progress on some sparser graphs. Fox and Lin observed that s(H) 2δ(H)-1 for all graphs H, where δ(H) is the minimum degree of H; Szabo, Zumstein, and Zurcher investigated which graphs have this property and conjectured that all bipartite graphs H without isolated vertices satisfy s(H)=2δ(H)-1. Fox, Grinshpun, Liebenau, Person, and Szabo further conjectured that all triangle-free graphs without isolated vertices satisfy this property. We show that d-regular 3-connected triangle-free graphs H, with one extra technical constraint, satisfy s(H) = 2δ(H)-1; the extra constraint is that H has a vertex v so that if one removes v and its neighborhood from H, the remainder is connected.