Spectral supersaturation: Triangles and bowties
Abstract
Recently, Ning and Zhai (2023) proved that every n-vertex graph G with λ (G) n2/4 has at least n/2 -1 triangles, unless G=K n2 , n2 . The aim of this paper is two-fold. Using the supersaturation-stability method, we prove a stability variant of Ning-Zhai's result by showing that such a graph G contains at least n-3 triangles if no vertex is in all triangles of G. This result could also be viewed as a spectral version of a result of Xiao and Katona (2021). The second part concerns with the spectral supersaturation for the bowtie, which consists of two triangles sharing a common vertex. A theorem of Erdos, F\"uredi, Gould and Gunderson (1995) says that every n-vertex graph with more than n2/4 +1 edges contains a bowtie. For graphs of given order, the spectral supersaturation problem has not been considered for substructures that are not color-critical. In this paper, we give the first such theorem by counting the number of bowties. Let K n2 , n2 +2 be the graph obtained from K n2 , n2 by embedding two disjoint edges into the vertex part of size n2 . Our result shows that every graph G with n 8.8 × 106 vertices and λ (G) λ (K n2 , n2 +2) contains at least n2 bowties, and K n2 , n2 +2 is the unique spectral extremal graph. This gives a spectral correspondence of a theorem of Kang, Makai and Pikhurko (2020). The method used in our paper provides a probable way to establish the spectral counting results for other graphs, even for non-color-critical graphs.
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