Cut‐and‐project quasicrystals, lattices and dense forests
Copyright policy )Cut‐and‐project quasicrystals, lattices and dense forests
Dense forests are discrete subsets of Euclidean space which are uniformly close to all sufficiently long line segments. The degree of density of a dense forest is measured by its visibility function. We show that cut-and-project quasicrystals are never dense forests, but their finite unions could be uniformly discrete dense forests. On the other hand, we show that finite unions of lattices typically are dense forests, and give a bound on their visibility function, which is close to optimal. We also construct an explicit finite union of lattices which is a uniformly discrete dense forest with an explicit bound on its visibility.
This version includes a picture provided by the referee and a subsection relating the theory developed in this paper to the properties of twisted bilayer graphene in physics
Mathematics - Number Theory, Mathematics - Metric Geometry, FOS: Mathematics, Metric Geometry (math.MG), [MATH] Mathematics [math], Number Theory (math.NT)
Mathematics - Number Theory, Mathematics - Metric Geometry, FOS: Mathematics, Metric Geometry (math.MG), [MATH] Mathematics [math], Number Theory (math.NT)
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