Counting color-critical subgraphs under Nikiforov's condition
Abstract
For a graph G with m edges, let (G) be its spectral radius, and let NF(G) denote the number of copies of F in G. Nikiforov [Combin. Probab.\,Comput., 2002] proved that for r≥ 2, if (G)>(1-1/r)2m, then NKr+1(G)≥ 1. Furthermore, Bollob\'as and Nikiforov [J. Combin. Theory, Ser. B, 2007] used (G) to establish a counting inequality for complete subgraphs. In this paper, we generalize and strengthen the above results to any color-critical graph F with chromatic number at least four. More precisely, we demonstrated that under Nikiforov's condition, the number of copies of F in G satisfies NF(G)≥(γF-o(1))m(|F|-2)/2, where both the leading item and the constant γF are optimal. Let F be a non-star graph with (F)=r+1, and let G be any graph of sufficiently large size m satisfying NF(G)=o(m|F|/2). To support the aforementioned counting arguments, we initially employ the method of progressive induction to tackle spectral problems, proving that (G)≤(1-1/r+o(1))2m for r≥ 3, and (G)≤(1+o(1))m for r∈ \1,2\. Furthermore, we establish a stability result for edge-spectral supersaturation: specifically, if r≥ 3 and (G)≥(1-1/r-o(1))2m, then G differs from an r-partite Tur\'an graph by o(m) edges; if r∈ \1,2\ and (G)≥(1-o(1))m, then G differs from a complete bipartite graph by o(m) edges. This implies the well-known Erdos-Simonovits stability theorem and existing spectral stability theorems, by strengthening the setting from F-free graphs to graphs containing only a limited number of copies of F. Finally, we propose several counting-related open problems for further investigation.
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