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Main Authors: Griffin, Thomas, Lathrop, James, Parshad, Rana
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2312.03947
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author Griffin, Thomas
Lathrop, James
Parshad, Rana
author_facet Griffin, Thomas
Lathrop, James
Parshad, Rana
contents The classical chemostat is an intensely investigated model in ecology and bio/chemical engineering, where n-species, say $x_{1}, x_{2}...x_{n}$ compete for a single growth limiting nutrient. Classical theory predicts that depending on model parameters, one species competitively excludes all others. Furthermore, this ''order'' of strongest to weakest is preserved, $x_{1} >> x_{2} >> ...x_{n}$, for say $D_{1} < D_{2} <...D_{n}$, where $D_{i}$ is the net removal of species $x_{i}$. Meaning $x_{1}$ is the strongest or most dominant species and $x_{n}$ is the weakest or least dominant. We propose a modified version of the classical chemostat, exhibiting certain counterintuitive dynamics. Herein we show that if only a certain proportion of the weakest species $x_{n}$'s population is removed at a ''very'' fast density dependent rate, it will in fact be able to competitively exclude all other species, for certain initial conditions. Numerical simulations are carried out to visualize these dynamics in the three species case.
format Preprint
id arxiv_https___arxiv_org_abs_2312_03947
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle A modified chemostat exhibiting competitive exclusion "reversal"
Griffin, Thomas
Lathrop, James
Parshad, Rana
Dynamical Systems
The classical chemostat is an intensely investigated model in ecology and bio/chemical engineering, where n-species, say $x_{1}, x_{2}...x_{n}$ compete for a single growth limiting nutrient. Classical theory predicts that depending on model parameters, one species competitively excludes all others. Furthermore, this ''order'' of strongest to weakest is preserved, $x_{1} >> x_{2} >> ...x_{n}$, for say $D_{1} < D_{2} <...D_{n}$, where $D_{i}$ is the net removal of species $x_{i}$. Meaning $x_{1}$ is the strongest or most dominant species and $x_{n}$ is the weakest or least dominant. We propose a modified version of the classical chemostat, exhibiting certain counterintuitive dynamics. Herein we show that if only a certain proportion of the weakest species $x_{n}$'s population is removed at a ''very'' fast density dependent rate, it will in fact be able to competitively exclude all other species, for certain initial conditions. Numerical simulations are carried out to visualize these dynamics in the three species case.
title A modified chemostat exhibiting competitive exclusion "reversal"
topic Dynamical Systems
url https://arxiv.org/abs/2312.03947