Random Growth via Gradient Flow Aggregation

Abstract

We introduce Gradient Flow Aggregation (GFA), a random growth model. Given a set of existing particles \x1, …, xn\ ⊂ R2, a new particle arrives from a random direction at ∞ and flows in direction ∇ E where E(x) = Σi=1n 1\|x-xi\|α where ~0 < α < ∞. The case α = 0 will refer to the logarithmic energy - Σ \|x-xi\|. Particles stop once they are at distance 1 of one of the existing particles at which point they are added to the set and remain fixed for all time. We prove, under a non-degeneracy assumption, a Beurling-type estimate which, via Kesten's method, can be used to deduce sub-ballistic growth for 0 ≤ α < 1 diam(\x1, …, xn\) ≤ cα · n3 α +12α + 2. This is optimal when α =0. The case α = 0 leads to a `round' full-dimensional tree. The larger the value of α the sparser the tree. Some instances of the higher-dimensional setting are also discussed.