English

Spanning Trees and Mahler Measure

Combinatorics 2016-02-10 v1 Geometric Topology

Abstract

The complexity of a finite connected graph is its number of spanning trees; for a non-connected graph it is the product of complexities of its connected components. If GG is an infinite graph with cofinite free Zd{\mathbb Z}^d-symmetry, then the logarithmic Mahler measure m(Δ)m(\Delta) of its Laplacian polynomial Δ\Delta is the exponential growth rate of the complexity of finite quotients of GG. It is bounded below by m(Δ(Gd))m(\Delta({\mathbb G}_d)), where Gd{\mathbb G}_d is the grid graph of dimension dd. The growth rates m(Δ(Gd))m(\Delta({\mathbb G}_d)) are asymptotic to log2d\log 2d as dd tends to infinity. If m(Δ(G))0m(\Delta(G))\ne 0, then m(Δ(G))log2m(\Delta(G)) \ge \log 2. An application to determinant growth rates of families of alternating links arising from planar graphs is given.

Keywords

Cite

@article{arxiv.1602.02797,
  title  = {Spanning Trees and Mahler Measure},
  author = {Daniel S. Silver and Susan G. Williams},
  journal= {arXiv preprint arXiv:1602.02797},
  year   = {2016}
}

Comments

12 pages, 1 figure

R2 v1 2026-06-22T12:46:04.541Z