Exceptional times when bigeodesics exist in dynamical last passage percolation
Abstract
It is believed that, under very general conditions, doubly infinite geodesics (or bigeodesics) do not exist for planar first and last passage percolation (LPP) models. However, if one endows the model with a natural dynamics, thereby gradually perturbing the geometry, then it is plausible that there could exist a non-trivial set of exceptional times $\mathscr{T}$ at which such bigeodesics exist, and the objective of this paper is to investigate this set. For dynamical exponential LPP, we obtain an $\Omega( 1/\log n)$ lower bound on the probability that there exists a random time $t\in [0,1]$ at which a geodesic of length $n$ passes through the origin at its midpoint -- note that this is slightly short of proving the non-triviality of the set $\mathscr{T}$ which would instead require an $\Omega(1)$ lower bound. In the other direction, working with a dynamical version of Brownian LPP, we show that the average total number of changes that a geodesic of length $n$ accumulates in unit time is at most $n^{5/3+o(1)}$; using this, we establish that the Hausdorff dimension of $\mathscr{T}$ is a.s. upper bounded by $1/2$. Further, for a fixed angle $\theta$, we show that the set $\mathscr{T}^\theta\subseteq \mathscr{T}$ of exceptional times at which a $\theta$-directed bigeodesic exists a.s. has Hausdorff dimension zero. We provide a list of open questions.