English

Persistence in fluctuating environments for interacting structured populations

Populations and Evolution 2015-12-16 v2 Dynamical Systems Probability

Abstract

Individuals within any species exhibit differences in size, developmental state, or spatial location. These differences coupled with environmental fluctuations in demographic rates can have subtle effects on population persistence and species coexistence. To understand these effects, we provide a general theory for coexistence of structured, interacting species living in a stochastic environment. The theory is applicable to nonlinear, multi species matrix models with stochastically varying parameters. The theory relies on long-term growth rates of species corresponding to the dominant Lyapunov exponents of random matrix products. Our coexistence criterion requires that a convex combination of these long-term growth rates is positive with probability one whenever one or more species are at low density. When this condition holds, the community is stochastically persistent: the fraction of time that a species density goes below δ>0\delta>0 approaches zero as δ\delta approaches zero. Applications to predator-prey interactions in an autocorrelated environment, a stochastic LPA model, and spatial lottery models are provided. These applications demonstrate that positive autocorrelations in temporal fluctuations can disrupt predator-prey coexistence, fluctuations in log-fecundity can facilitate persistence in structured populations, and long-lived, relatively sedentary competing populations are likely to coexist in spatially and temporally heterogenous environments.

Keywords

Cite

@article{arxiv.1304.1862,
  title  = {Persistence in fluctuating environments for interacting structured populations},
  author = {Gregory Roth and Sebastian J. Schreiber},
  journal= {arXiv preprint arXiv:1304.1862},
  year   = {2015}
}

Comments

41 pages, 3 figures; Accepted for publication in Journal of Mathematical Biology

R2 v1 2026-06-21T23:54:53.126Z