Strict inequality between the time constants of first-passage percolation and directed first-passage percolation

Abstract

In the models of first-passage percolation and directed first-passage percolation on Zd, we consider a family of i.i.d. random variables indexed by the set of edges of the graph, called passage times. For every vertex x ∈ Zd with nonnegative coordinates, we denote by t(0,x) the shortest passage time to go from 0 to x and by t(0,x) the shortest passage time to go from 0 to x following a directed path. Under some assumptions, it is known that for every x ∈ Rd with nonnegative coordinates, t(0, nx )/n converges to a constant μ(x) and that t(0, nx )/n converges to a constant μ(x). With these definitions, we immediately get that μ(x) μ(x). In this paper, we get the strict inequality μ(x) < μ(x) as a consequence of a new exponential bound for the comparison of t(0,x) and t(0,x) when \|x\| goes to ∞. This exponential bound is itself based on a lower bound on the number of edges of geodesics in first-passage percolation (where geodesics are paths with minimal passage time).

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