On Some Multicolor Ramsey Numbers Involving K3+e and K4-e

Abstract

The Ramsey number R(G1, G2, G3) is the smallest positive integer n such that for all 3-colorings of the edges of Kn there is a monochromatic G1 in the first color, G2 in the second color, or G3 in the third color. We study the bounds on various 3-color Ramsey numbers R(G1, G2, G3), where Gi ∈ \K3, K3+e, K4-e, K4\. The minimal and maximal combinations of Gi's correspond to the classical Ramsey numbers R3(K3) and R3(K4), respectively, where R3(G) = R(G, G, G). Here, we focus on the much less studied combinations between these two cases. Through computational and theoretical means we establish that R(K3, K3, K4-e)=17, and by construction we raise the lower bounds on R(K3, K4-e, K4-e) and R(K4, K4-e, K4-e). For some G and H it was known that R(K3, G, H)=R(K3+e, G, H); we prove this is true for several more cases including R(K3, K3, K4-e) = R(K3+e, K3+e, K4-e). Ramsey numbers generalize to more colors, such as in the famous 4-color case of R4(K3), where monochromatic triangles are avoided. It is known that 51 ≤ R4(K3) ≤ 62. We prove a surprising theorem stating that if R4(K3)=51 then R4(K3+e)=52, otherwise R4(K3+e)=R4(K3).