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arxiv: 2509.08077 · v3 · pith:4GBXL4XO · submitted 2025-09-09 · cond-mat.stat-mech · q-bio.PE

Self-organized hyperuniformity in a minimal model of population dynamics

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classification cond-mat.stat-mech q-bio.PE
keywords modelhyperuniformitypopulationdynamicshyperuniformmodelsaccountapplications
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By generalizing a class of models recently introduced to account for protracted transients in biological systems, we identify a novel mechanism for hyperuniformity. In this model, competition of individuals over a shared resource serves as feedback that can asymptotically guide the population towards a critical steady state with divergent individual life time. We show that, in its spatially extended form, this many-body model exhibits hyperuniform density fluctuations. Through explicit coarse-graining, we develop a hydrodynamic theory that conforms closely with the results of stochastic simulations. Unlike previous models for non-equilibrium hyperuniform states, our model does not exhibit conservation laws, even in the asymptotic regime. Instead, hyperuniformity arises from the divergence of the range of the resource-mediated interactions. These findings may find applications in engineering, cellular population dynamics, and ecology.

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Cited by 2 Pith papers

Reviewed papers in the Pith corpus that reference this work. Sorted by Pith novelty score.

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    Time integration of stochastic Turing patterns in the Levin-Segel model yields effective hyperuniformity with intensive number variance approaching a reaction-kinetic floor as 1/R near the Turing instability.

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    Competition pins multicomponent systems to marginal stability of the most persistent species, implementing compositional proofreading via extended lifetimes of dominant components and rapid turnover of others.