Thick embeddings of graphs into symmetric spaces via coarse geometry

Abstract

We prove estimates for the optimal volume of thick embeddings of finite graphs into symmetric spaces, generalising results of Kolmogorov-Barzdin and Gromov-Guth for embeddings into Euclidean spaces. We distinguish two very different behaviours depending on the rank of the non-compact factor. For rank at least 2, we construct thick embeddings of N-vertex graphs with volume CN(1+N) and prove that this is optimal. For rank at most 1 we prove lower bounds of the form cNa for some (explicit) a>1 which depends on the dimension of the Euclidean factor and the conformal dimension of the boundary of the non-compact factor. The main tool is a coarse geometric analogue of a thick embedding called a coarse wiring, with the key property that the minimal volume of a thick embedding is comparable to the ``minimal volume'' of a coarse wiring for symmetric spaces of dimension at least 3. In the appendix it is proved that for each k≥ 3 every bounded degree graph admits a coarse wiring into Rk with volume at most CN1+1k-1. As a corollary, the same upper bound holds for real hyperbolic space of dimension k+1 and in both cases this result is optimal.

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