First-order behavior of the time constant in non-isotropic continuous first-passage percolation

Abstract

Consider a homogeneous Poisson point process on Rd (d≥ 2) with unit intensity with respect to the Lebesgue measure. For ≥ 0, we define the Boolean model p, as the union of the balls of volume for the p-norm (p∈ [1,∞]) and centered at the points of . We define a random pseudo-metric on Rd by associating with any path a travel time equal to its p-length outside p,. This defines a continuous model of first-passage percolation, that has been studied in GT17,GT22 for p=2, the Euclidean norm. For p=1, this model is expected to share common properties with the classical first-passage percolation on the graph Zd with a distribution of passage times of the form δ0 + (1-) δ1. The exact calculation of the time constant of this model μp, (x) is out of reach. We investigate here the behavior of μp, (x) near 0, and enlighten how the speed at which \| x \|p - μp, (x) goes to 0 depends on x and p. For instance, for p∈ (1,∞), we prove that \| x \|p - μp,ε (x) is of order p(x) with p(x): = 1d- d1(x)-12 - d-d1 (x)p\,,where d1(x) is the number of non null coordinates of x. The exact order of \| x \|p - μp,ε (x) is also given for p=1 and p=∞. Related results are also discussed, about properties of the geodesics, and analog properties on closely related models.