Arithmetic oscillations of the chemical distance in long-range percolation on Zd
Abstract
We consider a long-range percolation graph on Zd where, in addition to the nearest-neighbor edges of Zd, distinct x,y∈ Zd are connected by an edge independently with probability asymptotic to β|x-y|-s, for s∈(d,2d), β>0 and |·| a norm on Rd. We first show that, for all but a countably many β>0, the graph-theoretical (a.k.a. chemical) distance between typical vertices at |·|-distance r is, with high probability as r∞, asymptotic to φβ(r)( r), where -1:=2(2d/s) and φβ is a positive, bounded and continuous function subject to φβ(rγ)=φβ(r) for γ:=s/(2d). The proof parallels that in a continuum version of the model where a similar scaling was shown earlier by the first author and J. Lin. This work also conjectured that φβ is constant which we show to be false by proving that (β)φβ tends, as β∞, to a non-constant limit which is independent of the specifics of the model. The proof reveals arithmetic rigidity of the shortest paths that maintain a hierarchical (dyadic) structure all the way to unit scales.
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