The Directed Spanning Forest: coalescence versus dimension

Abstract

For p∈[1,∞], the p directed spanning forest (DSF) of dimension d≥ 2 is an oriented random geometric graph whose vertex set is given by a homogeneous Poisson point process N on Rd and whose edges consist of all pairs (x, y)∈ N2 such that y is the closest point to x in N for the p distance among points with a strictly larger ed coordinate. First introduced by Baccelli and Bordenave in 2007 in the case p=d=2, this graph has a natural forest structure. In this work, we study the number of disjoint trees in the p DSF for arbitrary dimensions d≥2 and various values of p∈ [1,∞]. We prove that for p∈\1, 2,∞\, the graph is almost surely a tree when d=3, and consists of infinitely many disjoint trees when d≥ 4. Additionally, we show that for all p∈[1,∞], the DSF in dimension 2 is almost surely a tree and, under appropriate diffusive scaling, converges weakly to the Brownian web, generalizing the result previously known for p=2. Although these results were expected from a heuristic point of view, and the main strategies and tools were largely understood, extending them beyond the planar setting (d=2) and to the singular case p=∞ presented a significant challenge. Notably, in the absence of planarity, which plays a crucial role in existing arguments, delicate and innovative techniques were required to manage the complex geometric dependencies of the model. We develop substantially new ideas to handle arbitrary dimension d≥2 and various values of p∈ [1,∞] within a unified framework. In particular, we introduce a novel stochastic domination argument that allows us to compare the fully dependent model with a simplified version in which the geometric correlations are suppressed.