Let H1,H2, . . .,Hk+1 be a sequence of k+1 finite, undirected, simple graphs. The (multicolored) Ramsey number r(H1,H2,...,Hk+1) is the minimum integer r such that in every edge-coloring of the complete graph on r vertices by k+1 colors, there is a monochromatic copy of Hi in color i for some 1≤i≤k+1. We describe a general technique that supplies tight lower bounds for several numbers r(H1,H2,...,Hk+1) when k≥2, and the last graph Hk+1 is the complete graph Km on m vertices. This technique enables us to determine the asymptotic behaviour of these numbers, up to a polylogarithmic factor, in various cases. In particular we show that r(K3,K3,Km) = Θ(m3 poly logm), thus solving (in a strong form) a conjecture of Erdőos and Sós raised in 1979. Another special case of our result implies that r(C4,C4,Km) = Θ(m2 poly logm) and that r(C4,C4,C4,Km) = Θ(m2/log2m). The proofs combine combinatorial and probabilistic arguments with spectral techniques and certain estimates of character sums.
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