Title: Self-organized criticality explains the emergence of irregular vegetation patterns in semi-arid regionsOral:

Vegetation patterns in semi-arid areas manifest either through regular or irregular vegetation patches separated by bare ground. Of particular interest are the latter structures, that exhibit a distinctive power-law distribution of patch sizes. While a Turing-like instability mechanism can explain the formation of regular patterns, the emergence of irregular ones still lacks a clear understanding. To fill this gap, we present a novel self-organizing criticality mechanism driving the emergence of irregular vegetation patterns in semi-arid landscapes. The model integrates essential ecological principles, emphasizing positive interactions and limited resources. It consists of a single-species evolution equation with an Allee-logistic reaction term and a nonlinear diffusion one accounting for self-segregation. The model captures an initial mass decrease due to resource scarcity, reaching a predictable threshold. Beyond this threshold and due to local positive interactions that promote cooperation, vegetation self-segregates into distinct clusters. Numerical investigations show that the distribution of cluster sizes obeys a power law with an exponential cutoff, in accordance with empirical observations found in the literature. The study aims to establish a foundation for understanding self-organizing criticality in vegetation patterns, advancing the understanding of ecological pattern formation.