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A possible mechanism for the attainment of out-of-phase periodic dynamics in two chaotic subpopulations coupled at low dispersal rate

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dc.contributor.author Dey, Snigdhadip
dc.contributor.author Goswarni, Bedartha
dc.contributor.author Joshi, Amitabh
dc.date.accessioned 2016-12-22T11:45:58Z
dc.date.available 2016-12-22T11:45:58Z
dc.date.issued 2015
dc.identifier.citation Journal of Theoretical Biology en_US
dc.identifier.citation 367 en_US
dc.identifier.citation Dey, S.; Goswarni, B.; Joshi, A., A possible mechanism for the attainment of out-of-phase periodic dynamics in two chaotic subpopulations coupled at low dispersal rate. J. Theor. Biol. 2015, 367, 100-110. en_US
dc.identifier.issn 0022-5193
dc.identifier.uri https://libjncir.jncasr.ac.in/xmlui/10572/1973
dc.description Restricted access en_US
dc.description.abstract Much research in metapopulation dynamics has concentrated on identifying factors that affect coherence in spatially structured systems. In this regard, conditions for the attainment of out-of-phase dynamics have received considerable attention, due to the stabilizing effect of asynchrony on global dynamics. At low to moderate rates of dispersal, two coupled subpopulations with intrinsically chaotic dynamics tend to go out-of-phase with one another and also become periodic in their dynamics. The onset of out-of-phase dynamics and periodicity typically coincide. Here, we propose a possible mechanism for the onset of out-of-phase dynamics, and also the stabilization of chaos to periodicity, in two coupled subpopulations with intrinsically chaotic dynamics. We suggest that the onset of out-of-phase dynamics is due to the propensity of chaotic subpopulations governed by a steep, single-humped one-dimensional population growth model to repeatedly reach low subpopulation sizes that are close to a value N-t=A (A not equal equilibrium population size, K) for which Nt+1=K. Subpopulations with very similar low sizes, but on opposite sides of A, will become out-of-phase in the next generation, as they will end up at sizes on opposite sides of K, resulting in positive growth for one subpopulation and negative growth for the other. The key to the stabilization of out-of-phase periodic dynamics in this mechanism is the net effect of dispersal placing upper and lower bounds to subpopulation size in the two coupled subpopulations, once they have become out-of-phase. We tested various components of this proposed mechanism by simulations using the Ricker model, and the results of the simulations are consistent with predictions from the hypothesized mechanism. Similar results were also obtained using the logistic and Hassell models, and with the Ricker model incorporating the possibility of extinction, suggesting that the proposed mechanism could be key to the attainment and maintenance of out-of-phase periodicity in two-patch metapopulations where each patch has local dynamics governed by a single-humped population growth model. (C) 2014 Elsevier Ltd. All rights reserved. en_US
dc.description.uri 1095-8541 en_US
dc.description.uri http://dx.doi.org/10.1016/j.jtbi.2014.11.028 en_US
dc.language.iso English en_US
dc.publisher Academic Press Ltd- Elsevier Science Ltd en_US
dc.rights ?Academic Press Ltd- Elsevier Science Ltd, 2015 en_US
dc.subject Biology en_US
dc.subject Mathematical & Computational Biology en_US
dc.subject Metapopulation en_US
dc.subject Population growth models en_US
dc.subject Extinction en_US
dc.subject Stability en_US
dc.subject Chaos en_US
dc.subject Simple Population-Models en_US
dc.subject Metapopulations en_US
dc.subject Immigration en_US
dc.subject Extinction en_US
dc.subject Synchrony en_US
dc.subject Patterns en_US
dc.subject Stability en_US
dc.subject Behavior en_US
dc.subject Systems en_US
dc.title A possible mechanism for the attainment of out-of-phase periodic dynamics in two chaotic subpopulations coupled at low dispersal rate en_US
dc.type Article en_US


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