Fluctuation bounds for first-passage percolation on the square, tube, and torus

Abstract

In first-passage percolation, one assigns i.i.d. nonnegative weights (te) to the edges of Zd and studies the induced distance (passage time) T(x,y) between vertices x and y. It is known that for d=2, the fluctuations of T(x,y) are at least order |x-y| under mild assumptions on te. We study the question of fluctuation lower bounds for Tn, the minimal passage time between two opposite sides of an n by n square. The main result is that, under a curvature assumption, this quantity has fluctuations at least of order n1/8-ε for any ε>0 when the te are exponentially distributed. As previous arguments to bound the fluctuations of T(x,y) only give a constant lower bound for those of Tn (even assuming curvature), a different argument, representing Tn as a minimum of cylinder passage times, and deriving more detailed information about the distribution of cylinder times using the Markov property, is developed. As a corollary, we obtain the first polynomial lower bounds on higher central moments of the discrete torus passage time, under the same curvature assumption.