On the scaling of the chemical distance in long-range percolation models
Abstract
We consider the (unoriented) long-range percolation on Zd in dimensions d1, where distinct sites x,y∈ Zd get connected with probability pxy∈[0,1]. Assuming pxy=|x-y|-s+o(1) as |x-y|∞, where s>0 and |·| is a norm distance on Zd, and supposing that the resulting random graph contains an infinite connected component C∞, we let D(x,y) be the graph distance between x and y measured on C∞. Our main result is that, for s∈(d,2d), D(x,y)=(|x-y|)+o(1), x,y∈ C∞, |x-y|∞, where -1 is the binary logarithm of 2d/s and o(1) is a quantity tending to zero in probability as |x-y|∞. Besides its interest for general percolation theory, this result sheds some light on a question that has recently surfaced in the context of ``small-world'' phenomena. As part of the proof we also establish tight bounds on the probability that the largest connected component in a finite box contains a positive fraction of all sites in the box.
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