Finite projective planes meet spectral gaps
Abstract
We show that for any connected graph $G$ with maximum degree $d\ge3$, the spectral gap from $0$ with respect to the adjacency matrix is at most $\sqrt{d-1}$. We further show that the upper bound $\sqrt{d-1}$ is achieved if and only if $G$ is the incidence graph of a finite projective plane of order $d-1$; and for other cases, the upper bound can be improved to $\sqrt{d-2}$. A similar yet more subtle phenomenon involving the normalized Laplacian is also investigated, in which we work on graphs of degrees $\ge d$ rather than $\le d$. We prove that for any graph $G$ with \emph{minimum} degree $d\ge 3$, the spectral gap from the value 1 with respect to the normalized Laplacian is at most $\sqrt{d-1}/d$, with equality if and only if $G$ is the incidence graph of a finite projective plane of order $d-1$. These results are spectral gap analogues to an inequality involving HL-index by Mohar and Tayfeh-Rezaie, as well as an estimate of the energy per vertex by van Dam, Haemers and Koolen. Moreover, we provide a new sharp bound for the convergence rate of some eigenvalues of the Laplacian on the (weighted) neighborhood graphs introduced by Bauer and Jost.