Coexistence of many species under a random competition–colonization trade-off

Miller, Zachary R.; Clenet, Maxime; Della Libera, Katja; Massol, François; Allesina, Stefano

doi:10.1073/pnas.2314215121

Cited by 4 publications

(1 citation statement)

References 71 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Replicator dynamics have been used extensively in theoretical ecology to model ecosystem interactions at a high level [1][2][3]. Surprisingly, these models intersect those from theoretical physics, with tournament dynamics in ecology [4,5] also occurring in the analysis of the Schrödinger operator [6] and in the discrete KdV equation [7].…”

Section: Introductionmentioning

confidence: 99%

Spatial dynamics of higher order rock-paper-scissors and generalisations

Griffin,

Feng,

2024

J. Phys. A: Math. Theor.

View full text Add to dashboard Cite

We introduce and study the spatial replicator equation with higher order interactions and both infinite (spatially homogeneous) populations and finite (spatially inhomogeneous) populations. We show that in the special case of three strategies (rock-paper-scissors) higher order interaction terms allow travelling waves to emerge in non-declining finite populations. We show that these travelling waves arise from diffusion stabilisation of an unstable interior equilibrium point that is present in the aspatial dynamics. Based on these observations and prior results, we offer two conjectures whose proofs would fully generalise our results to all odd cyclic games, both with and without higher order interactions, assuming a spatial replicator dynamic. Intriguingly, these generalisations for $N \geq 5$ strategies seem to require declining populations, as we show in our discussion.

show abstract

Section: Introductionmentioning

confidence: 99%

Spatial dynamics of higher order rock-paper-scissors and generalisations

Griffin,

Feng,

2024

J. Phys. A: Math. Theor.

View full text Add to dashboard Cite

show abstract

Community recomposition caused by species extinction in the colonization-competition trade-off model for vegetation

Nothaaß,

Huth

2025

Ecological Modelling

View full text Add to dashboard Cite

Selection on sporulation strategies in a metapopulation can lead to coexistence

Proulx,

Sakal,

Reitz

et al. 2024

Evolution

View full text Add to dashboard Cite

In constant environments the coexistence of similar species or genotypes is generally limited. In a metapopulation context, however, types that utilize the same resource but are distributed along a competition-colonization trade-off, can coexist. Much thought in this area focuses on a generic trade-off between within-deme competitive ability and between-deme dispersal ability. We point out that the sporulation program in yeasts and other microbes can create a natural trade-off such that strains which initiate sporulation at higher rates suffer in terms of within-deme competition but benefit in terms of between deme dispersal. We develop metapopulation models where the within- deme behavior follows chemostat dynamics. We first show that the rate of sporulation determines the colonization ability of the strain, with colonization ability increasing with sporulation rate up to a point. Metapopulation stability of a single strain exists in a defined range of sporulation rates. We then use pairwise invasability plots to show that coexistence of strains with different sporulation rates generally occurs, but that the set of sporulation rates that can potentially coexist is smaller than the set that allows for stable metapopulations. We extend our pairwise results to show how a continuous set of strains can coexist and verify our conclusions with numerical calculations and stochastic simulations. Our results show that stable variation in sporulation rates is expected under a wide range of ecological conditions.

show abstract

Coexistence of many species under a random competition–colonization trade-off

Cited by 4 publications

References 71 publications

Spatial dynamics of higher order rock-paper-scissors and generalisations

Spatial dynamics of higher order rock-paper-scissors and generalisations

Community recomposition caused by species extinction in the colonization-competition trade-off model for vegetation

Selection on sporulation strategies in a metapopulation can lead to coexistence

Contact Info

Product

Resources

About