Monochromatic cycles in 2-edge-colored bipartite graphs with large minimum degree

Abstract

For graphs G0, G1 and G2, write G0(G1, G2) if each red-blue-edge-coloring of G0 yields a red G1 or a blue G2. The Ramsey number r(G1, G2) is the minimum number n such that the complete graph Kn(G1, G2). In [Discrete Math. 312(2012)], Schelp formulated the following question: for which graphs H there is a constant 0<c<1 such that for any graph G of order at least r(H, H) with δ(G)>c|V(G)|, G(H, H). In this paper, we prove that for any m>n, if G is a balanced bipartite graph of order 2(m+n-1) with δ(G)>34(m+n-1), then G(CMm, CMn), where CMi is a matching with i edges contained in a connected component. By Szem\'eredi's Regularity Lemma, using a similar idea as introduced by [J. Combin. Theory Ser. B 75(1999)], we show that for every η>0, there is an integer N0>0 such that for any N>N0 the following holds: Let α1>α2>0 such that α1+α2=1. Let G[X, Y] be a balanced bipartite graph on 2(N-1) vertices with δ(G)≥(34+3η)(N-1). Then for each red-blue-edge-coloring of G, either there exist red even cycles of each length in \4, 6, 8, …, (2-3η2)α1N\, or there exist blue even cycles of each length in \4, 6, 8, …, (2-3η2)α2N\. Furthermore, the bound δ(G)≥(34+3η)(N-1) is asymptotically tight. Previous studies on Schelp's question on cycles are on diagonal case, we obtain an asymptotic result of Schelp's question for all non-diagonal cases.