Graph operations and a unified method for kinds of Tur\'an-type problems on paths, cycles and matchings
Abstract
Let G be a connected graph and P(G) a graph parameter. We say that P(G) is feasible if P(G) satisfies the following properties: (I) P(G)≤ P(Guv), if Guv=G[u v] for any u,v, where Guv is the graph obtained by applying Kelmans operation from u to v; (II) P(G) <P(G+e) for any edge e E(G). Let Pk be a path of order k, C≥ k the set of all cycles of length at least k and Mk+1 a matching containing k+1 independent edges. In this paper, we mainly prove the following three results: (i) Let n≥ k≥ 5 and let t=k-12. Let G be a 2-connected n-vertex C≥ k-free graph with the maximum P(G) where P(G) is feasible. Then, G∈ G1n,k=\Wn,k,s=Ks ((n-k+s)K1 Kk-2s): 2≤ s≤ t\. (ii) Let n≥ k≥ 4 and let t=k2-1. Let G be a connected n-vertex Pk-free graph with the maximum P(G) where P(G) is feasible. Then, G∈ G2n,k=\Wn,k-1,s=Ks ((n-k+s+1)K1 Kk-2s-1): 1≤ s≤ t\. (iii) Let G be a connected n-vertex Mk+1-free graph with the maximum P(G) where P(G) is feasible. Then, G Kn when n=2k+1 and G∈ G3n,k=\Ks ((n-2k+s-1)K1 K2k-2s+1):1≤ s≤ k\ when n≥ 2k+2. Directly derived from these three main results, we obtain a series of applications in Tur\'an-type problems, generalized Tur\'an-type problems, powers of graph degrees in extremal graph theory, and problems related to spectral radius, and signless Laplacian spectral radius in spectral graph theory.
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