Self-organized hyperuniformity in a minimal model of population dynamics
Abstract
We identify a novel scenario for hyperuniformity in a generic model of population dynamics that has been recently introduced to account for biological memory in the immune system and epigenetic inheritance. In this model, individuals' competition over a shared resource guides the population towards a critical steady state with prolonged individual life time. Here we uncover that the spatially extended model is characterized by hyperuniform density fluctuations. A hydrodynamic theory is derived by explicit coarse-graining, which shows good agreement with numerical simulations. Unlike previous models for non-equilibrium hyperuniform states, our model does not exhibit conservation laws, even when approaching criticality. Instead, we trace the emergence of hyperuniformity to the divergence of timescales close to criticality. These findings can have applications in engineering, cellular population dynamics and ecology.