# Gromov's Hyperbolicity and Positive Cheeger Constant in Planar Graphs

It is known that for metric graphs the concepts of Gromov's hyperbolicity and strictly positive Cheeger constant are related. Let us first recall the definition of the Cheeger constant. Let $G$ be a graph with vertex set $V(G)$ and edge set $E(G)$. For a collection of vertices $A \subseteq V(G)$, let $\partial A$ denote the collection of all edges going from a vertex in $A$ to a vertex outside of $A$, $$\partial A := \{ (x, y) \in E : x \in A, y \in V(G) \setminus A \}.$$

Then the Cheeger constant of G, denoted $h(G)$, is defined as $$h(G) := \inf \left\{ \frac{|\partial A|}{|A|} : A \subseteq V(G)\quad\text{and}\quad |A|<\infty \right\}.$$

However, neither Gromov's hyperbolicity nor strictly positive Cheeger constant implies the other. For instance, the graph $\mathbb{Z}$ is hyperbolic in the sense of Gromov but its Cheeger constant is zero. On the other hand, the Cayley graph of the group $\mathbb{F}_{2}\times\mathbb{F}_2$ has positive Cheeger constant but it is not hyperbolic since $\mathbb{Z}\times \mathbb{Z}$ sits as a subgroup.

Does there exist a planar graph with positive Cheeger constant but not hyperbolic?

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Could you explain how 'the concepts of Gromov's hyperbolicity and strictly positive Cheeger constant are related'? – HJRW Mar 27 '11 at 18:10
I think this is one definition of a Gromov hyperbolic graph: any two of its geodesics are either parallel or diverge exponentially. Maybe Gabriel can elaborate further ... – Joseph O'Rourke Mar 27 '11 at 19:20
@HW: See the paper for a more detailed discussion: "Cheeger Isoperimetric Constants of Gromov-Hyperbolic Spaces with Quasi-Poles" by J. Cao, published in Communications in Contemporary Mathematics, Vol. 2, No. 4, pp. 511–533, 2000. @Joseph: The definition of Gromov's hyperbolic graph is that there exists $\delta>0$ such that all the geodesic triangles in the graph are $\delta$ thin. This means that any side of a triangle is in the $\delta$ neighborhood of the other two. As you said this implies that every two geodesic rays starting in a point diverge exponentially – ght Mar 27 '11 at 19:36
@Gabriel, thanks for the reference. Regarding Joseph's comment, there are many definitions of $\delta$-hyperbolicity - indeed, the definition that you give is, I believe, due to Rips, not Gromov. I think the heart of Joseph's claim is that the converse of the proposition you state is also true. – HJRW Mar 27 '11 at 20:08

However, if you allow the dual graph to have unbounded degree (say), there are examples. Let $T$ be the regular degree $3$ tree. Note that $h(T) > 0$. Properly embed $T$ in the plane. Let $C_i$ be an ordering of the complementary regions. Now add a single edge $e_i$, in the interior of $C_i$, so that $C_i$ is divided into two regions, one compact and the other not compact. We add the edge so that the compact region is bounded by a cycle of length $i$.
Let $T' = T \cup (\cup e_i)$. The cycles created above prevent $T'$ from being Gromov hyperbolic. However $h(T') \geq h(T)$ as adding edges does not decrease the Cheeger constant.
For the first paragraph: Let $\gamma$ be a simple loop in the plane, transverse to the given graph and meeting every complementary region at most once. We need to prove that there is a constant $K$ so that the area of $\gamma$ is bounded by $K$ times its length. So we must define length and area. Length will be the number of edges traversed in the dual graph and area to be number of vertices contained in the bounded disk. The linear isoperimetric inequality now follows from positivity of $h$. – Sam Nead Mar 27 '11 at 20:35