Non-equilibrium multi-scale analysis and coexistence in competing first passage percolation

TL;DR

This paper introduces a novel multi-scale analysis approach with non-equilibrium feedback to study a competitive first passage percolation model on b, demonstrating coexistence and positive density occupation of competing processes.

Contribution

It develops a new analysis method for non-equilibrium, non-monotone processes and proves coexistence in a competitive percolation model on b, answering an open question.

Findings

Established coexistence phase for the model in b for d
3.

Proved both processes can occupy a positive density of sites.

Demonstrated coexistence with different speeds in a natural competition model.

Abstract

The main contribution of this paper is the development of a novel approach to multi-scale analysis that we believe can be used to analyse processes with non-equilibrium dynamics. Our approach will be referred to as \emph{multi-scale analysis with non-equilibrium feedback} and will be used to analyse a natural random growth process with competition on $\mathbb{Z}^d$ called \emph{first passage percolation in a hostile environment} that consists of two first passage percolation processes $FPP_1$ and $FPP_{\lambda}$ that compete for the occupancy of sites. Initially, $FPP_1$ occupies the origin and spreads through the edges of $\mathbb{Z}^d$ at rate 1, while $FPP_{\lambda}$ is initialised at sites called \emph{seeds} that are distributed according to a product of Bernoulli measures of parameter $p\in(0,1)$, where a seed remains dormant until $FPP_1$ or $FPP_{\lambda}$ attempts to occupy it before then spreading through the edges of $\mathbb{Z}^d$ at rate $\lambda>0$. Particularly challenging aspects of FPPHE are its non-equilibrium dynamics and its lack of monotonicity (for instance, adding seeds could be benefitial to $FPP_1$ instead of $FPP_\lambda$); such characteristics, for example, prevent the application of a more standard multi-scale analysis. As a consequence of our main result for FPPHE, we establish a coexistence phase for the model for $d\geq3$, answering an open question in \cite{sidoravicius2019multi}. This exhibits a rare situation where a natural random competition model on $\mathbb{Z}^d$ observes coexistence for processes with \emph{different} speeds. Moreover, we are able to establish the stronger result that $FPP_1$ and $FPP_{\lambda}$ can both occupy a \emph{positive density} of sites with positive probability, which is in stark contrast with other competition processes.