Competitive Exclusion in a General Multi-species Chemostat Model with Stochastic Perturbations

Based on the fact that the continuous culture of microorganisms in a chemostat is subject to environmental noises, we present and analyze a stochastic competition chemostat model with general monotonic response functions and differential removal rates. The existence and boundedness of the unique pos...

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Veröffentlicht in:	Bulletin of mathematical biology 2021, Vol.83 (1), p.4-4, Article 4
Hauptverfasser:	Xu, Chaoqun, Yuan, Sanling, Zhang, Tonghua
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Sprache:	eng
Schlagworte:	Background noise Cell Biology Competition Continuous culture Life Sciences Mathematical and Computational Biology Mathematics Mathematics and Statistics Microorganisms Original Article Response functions Species
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creator	Xu, Chaoqun Yuan, Sanling Zhang, Tonghua
description	Based on the fact that the continuous culture of microorganisms in a chemostat is subject to environmental noises, we present and analyze a stochastic competition chemostat model with general monotonic response functions and differential removal rates. The existence and boundedness of the unique positive solution are first obtained. By defining a stochastic break-even concentration for every species, we prove that at most one competitor survives in the chemostat and the winner has the smallest stochastic break-even concentration, provided its response function satisfies a technical assumption. That is to say, the competitive exclusion principle holds for the stochastic competition chemostat model. Furthermore, we find that the noise experienced by one species is adverse to its growth while may be favorable for the growth of other one species. Namely, the destinies can be exchanged between two microorganism species in the chemostat due to the environmental noise.
doi_str_mv	10.1007/s11538-020-00843-7
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subjects	Background noise Cell Biology Competition Continuous culture Life Sciences Mathematical and Computational Biology Mathematics Mathematics and Statistics Microorganisms Original Article Response functions Species
title	Competitive Exclusion in a General Multi-species Chemostat Model with Stochastic Perturbations
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