Nonlinear lattices from the physics of ecosystems: The Lefever-Lejeune nonlinear lattice in $\mathbb{Z}^2$

TL;DR

This paper explores how discretizing the Lefever-Lejeune ecosystem model into a 2D lattice reveals conditions for pattern formation and Turing instability, highlighting the role of spatial discreteness in ecological dynamics.

Contribution

It introduces a physically relevant nonlinear lattice model in two dimensions derived from a PDE, analyzing conditions for stability, extinction, and pattern formation.

Findings

Identifies parametric regimes for extinction and non-trivial states.

Derives analytical thresholds for Turing instability.

Numerical simulations confirm sharpness of analytical conditions and show rich pattern formation.

Abstract

We argue that the spatial discretization of the strongly nonlinear Lefever-Lejeune partial differential equation defines a nonlinear lattice that is physically relevant in the context of the nonlinear physics of ecosystems, modelling the dynamics of vegetation densities in dry lands. We study the system in the lattice $\mathbb{Z}^2$, which is especially relevant because of its natural dimension for the emergence of pattern formation. Theoretical results identify parametric regimes for the system that distinguish between extinction and potential convergence to non-trivial states. Importantly, we analytically identify conditions for Turing instability, detecting thresholds on the discretization parameter for the manifestation of this mechanism. Numerical simulations reveal the sharpness of the analytical conditions for instability and illustrate the rich potential for pattern formation even in the strongly discrete regime, emphasizing the importance of the interplay between higher dimensionality and discreteness.