Exceptional times when bigeodesics exist in dynamical last passage percolation (2504.12293v1)

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.