An upper bound on geodesic length in 2D critical first-passage percolation

Abstract

We consider i.i.d. first-passage percolation (FPP) on the two-dimensional square lattice, in the critical case where edge-weights take the value zero with probability 12. Critical FPP is unique in that the Euclidean lengths of geodesics are superlinear -- rather than linear -- in the distance between their endpoints. This fact was speculated by Kesten in 1986 but not confirmed until 2019 by Damron and Tang, who showed a lower bound on geodesic length that is polynomial with degree strictly greater than 1. In this paper, we establish the first nontrivial upper bound. Namely, we prove that for a large class of critical edge-weight distributions, the shortest geodesic from the origin to a box of radius R uses at most R2+επ3(R) edges with high probability, for any ε> 0. Here π3(R) is the polychromatic 3-arm probability from classical Bernoulli percolation; upon inserting its conjectural asymptotic, our bound converts to R4/3 + ε. In any case, it is known that π3(R) R-δ for some δ > 0, so our bound gives an exponent strictly less than 2. In the special case of Bernoulli(12) edge-weights, we replace the additional factor of Rε with a constant and give an expectation bound.