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Autores principales: Dauvergne, Duncan, Pankratz, Oliver Scott
Formato: Preprint
Publicado: 2026
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Acceso en línea:https://arxiv.org/abs/2602.09859
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author Dauvergne, Duncan
Pankratz, Oliver Scott
author_facet Dauvergne, Duncan
Pankratz, Oliver Scott
contents The directed landscape is a random directed metric on the plane that arises as the scaling limit of metric models in the KPZ universality class. For a pair of points p, q, the disjointness gap G(p; q) measures the shortfall when we optimize length over pairs of disjoint paths from p to q versus optimizing over all pairs of paths. Any spatial marginal of G is simply the gap between the top two lines in an Airy line ensemble. In this paper, we show that when the start and end time are fixed, the disjointness gap fully encodes the set of exceptional geodesic networks. The correspondence uses simple features of the disjointness gap, e.g. zeroes, local minima. We give a similar correspondence relating semi-infinite geodesic networks to a Busemann gap function. The proofs are deterministic given a list of soft properties related to the coalescent geometry of the directed landscape.
format Preprint
id arxiv_https___arxiv_org_abs_2602_09859
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Geodesic networks and the disjointness gap in the directed landscape
Dauvergne, Duncan
Pankratz, Oliver Scott
Probability
The directed landscape is a random directed metric on the plane that arises as the scaling limit of metric models in the KPZ universality class. For a pair of points p, q, the disjointness gap G(p; q) measures the shortfall when we optimize length over pairs of disjoint paths from p to q versus optimizing over all pairs of paths. Any spatial marginal of G is simply the gap between the top two lines in an Airy line ensemble. In this paper, we show that when the start and end time are fixed, the disjointness gap fully encodes the set of exceptional geodesic networks. The correspondence uses simple features of the disjointness gap, e.g. zeroes, local minima. We give a similar correspondence relating semi-infinite geodesic networks to a Busemann gap function. The proofs are deterministic given a list of soft properties related to the coalescent geometry of the directed landscape.
title Geodesic networks and the disjointness gap in the directed landscape
topic Probability
url https://arxiv.org/abs/2602.09859