Population size in stochastic multi-patch ecological models

TL;DR

This paper investigates how dispersal and environmental stochasticity affect population persistence and size in multi-patch ecological models, providing explicit approximations and analyzing the effects of different types of environmental fluctuations.

Contribution

It offers new analytical results on persistence, extinction, and population size under stochastic dispersal and environmental fluctuations, including explicit formulas for slow and fast dispersal scenarios.

Findings

Small dispersal with random carrying capacity reduces population size in Beverton-Holt models.

Random inverse carrying capacity increases population size in Hassell models.

Slow environmental switching can lead to higher population sizes than fast switching.

Abstract

We look at the interaction of dispersal and environmental stochasticity in $n$-patch models. We are able to prove persistence and extinction results even in the setting when the dispersal rates are stochastic. As applications we look at Beverton-Holt and Hassell functional responses. We find explicit approximations for the total population size at stationarity when we look at slow and fast dispersal. In particular, we show that if dispersal is small then in the Beverton-Holt setting, if the carrying capacity is random, then environmental fluctuations are always detrimental and decrease the total population size. Instead, in the Hassell setting, if the inverse of the carrying capacity is made random, then environmental fluctuations always increase the population size. Fast dispersal can save populations from extinction and therefore increase the total population size. We also analyze a different type of environmental fluctuation which comes from switching environmental states according to a Markov chain and find explicit approximations when the switching is either fast or slow - in examples we are able to show that slow switching leads to a higher population size than fast switching. Using and modifying some approximation results due to Cuello, we find expressions for the total population size in the $n=2$ patch setting when the growth rates, carrying capacities, and dispersal rates are influenced by random fluctuations. We find that there is a complicated interaction between the various terms and that the covariances between the various random parameters (growth rate, carrying capacity, dispersal rate) play a key role in whether we get an increase or a decrease in the total population size. Environmental fluctuations turn to sometimes be beneficial -- this show that not only dispersal, but also environmental stochasticity can lead to an increase in population size.