For a non-bipartite finite Cayley graph, we show the non-trivial eigenvalues of its normalized adjacency matrix lie in the interval $$\left[-1+\frac{ch_{out}^2}{d},1-\frac{Ch_{out}^2}{d}\right],$$ for some absolute constant $c$ and $C$, where $h_{out}$ stands for the outer vertex boundary isoperimetric constant. This improves upon recent obtained estimates aiming at a quantitative version of an observation due to Breuillard, Green, Guralnick and Tao stating that if a non-bipartite finite Cayley graph is an expander then the non-trivial eigenvalues of its normalized adjacency matrix is not only bounded away from $1$ but also bounded away from $-1$. We achieve this by extending the work of Bobkov, Houdr\'e and Tetali on vertex isoperimetry to the setting of signed graphs. We further extend our interval estimate to the settings of vertex transitive graphs and Cayley sum graphs, the latter of which need not be vertex transitive. Our approach answers positively recent open questions proposed by Moorman, Ralli and Tetali.
Comment: 28 pages. We extend our results for Cayley graphs to vertex transitive graphs and Cayley sum graphs in this version. The settings have been carefully discussed to allow multiple edges and multiple self-loops. All comments are welcome!