A Non-local Cross-Diffusion Model of Population Dynamics I: Emergent Spatial and Spatiotemporal Patterns

We extend a spatially non-local cross-diffusion model of aggregation between multiple species with directed motion toward resource gradients to include many species and more general kinds of dispersal. We first consider diffusive instabilities, determining that for directed motion along fecundity gr...

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Veröffentlicht in:	Bulletin of mathematical biology 2020-08, Vol.82 (8), p.112-112, Article 112
Hauptverfasser:	Taylor, Nick P., Kim, Hyunyeon, Krause, Andrew L., Van Gorder, Robert A.
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Schlagworte:	Advection Agglomeration Biology Cell Biology Colonies Colonies & territories Computer simulation Diffusion Dispersal Fecundity Heterogeneity Life Sciences Life Sciences & Biomedicine Life Sciences & Biomedicine - Other Topics Mathematical & Computational Biology Mathematical and Computational Biology Mathematical models Mathematics Mathematics and Statistics Motion stability Original Paper Population dynamics Science & Technology Spatial heterogeneity Spatial variations Species
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description	We extend a spatially non-local cross-diffusion model of aggregation between multiple species with directed motion toward resource gradients to include many species and more general kinds of dispersal. We first consider diffusive instabilities, determining that for directed motion along fecundity gradients, the model permits the Turing instability leading to colony formation and persistence provided there are three or more interacting species. We also prove that such patterning is not possible in the model under the Turing mechanism for two species under directed motion along fecundity gradients, confirming earlier findings in the literature. However, when the directed motion is not along fecundity gradients, for instance, if foraging or migration is sub-optimal relative to fecundity gradients, we find that very different colony structures can emerge. This generalization also permits colony formation for two interacting species. In the advection-dominated case, aggregation patterns are more broad and global in nature, due to the inherent non-local nature of the advection which permits directed motion over greater distances, whereas in the diffusion-dominated case, more highly localized patterns and colonies develop, owing to the localized nature of random diffusion. We also consider the interplay between Turing patterning and spatial heterogeneity in resources. We find that for small spatial variations, there will be a combination of Turing patterns and patterning due to spatial forcing from the resources, whereas for large resource variations, spatial or spatiotemporal patterning can be modified greatly from what is predicted on homogeneous domains. For each of these emergent behaviors, we outline the theoretical mechanism leading to colony formation and then provide numerical simulations to illustrate the results. We also discuss implications this model has for studies of directed motion in different ecological settings.
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In the advection-dominated case, aggregation patterns are more broad and global in nature, due to the inherent non-local nature of the advection which permits directed motion over greater distances, whereas in the diffusion-dominated case, more highly localized patterns and colonies develop, owing to the localized nature of random diffusion. We also consider the interplay between Turing patterning and spatial heterogeneity in resources. We find that for small spatial variations, there will be a combination of Turing patterns and patterning due to spatial forcing from the resources, whereas for large resource variations, spatial or spatiotemporal patterning can be modified greatly from what is predicted on homogeneous domains. For each of these emergent behaviors, we outline the theoretical mechanism leading to colony formation and then provide numerical simulations to illustrate the results. We also discuss implications this model has for studies of directed motion in different ecological settings.</description><subject>Advection</subject><subject>Agglomeration</subject><subject>Biology</subject><subject>Cell Biology</subject><subject>Colonies</subject><subject>Colonies & territories</subject><subject>Computer simulation</subject><subject>Diffusion</subject><subject>Dispersal</subject><subject>Fecundity</subject><subject>Heterogeneity</subject><subject>Life Sciences</subject><subject>Life Sciences & Biomedicine</subject><subject>Life Sciences & Biomedicine - Other Topics</subject><subject>Mathematical & Computational Biology</subject><subject>Mathematical and Computational Biology</subject><subject>Mathematical models</subject><subject>Mathematics</subject><subject>Mathematics and Statistics</subject><subject>Motion stability</subject><subject>Original Paper</subject><subject>Population dynamics</subject><subject>Science & Technology</subject><subject>Spatial heterogeneity</subject><subject>Spatial variations</subject><subject>Species</subject><issn>0092-8240</issn><issn>1522-9602</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2020</creationdate><recordtype>article</recordtype><sourceid>AOWDO</sourceid><recordid>eNqNkU1vFiEUhYnR2NdX_4ALM4kbE0O9wHyAu2b6mVRtoq4Jw0CdZgamwMS0v768nbYmLowr4PKcy-UchN4S2CcAzadISMU4Bgo4H3mNb5-hDakoxaIG-hxtAATFnJawh17FeAWZEky8RHuMNhxYBRv066D46h0evVZj0QYfIz4crF3i4F3xxfdmLLwtLvy8jCrtaoc3Tk2DjsXZ5-JoMuHSuFR8n_NlbqBcv-59MtPsQy5dqJRMcPE1emHVGM2bh3WLfh4f_WhP8fm3k7P24BzrkoiES6GtakDx3nRKA68pg6q2pFfCdF0jgCtBFO_6nlEiOJSkFj1RglZWl7Wo2RZ9WPvOwV8vJiY5DVGbcVTO-CVKWjLKK9GUVUbf_4Ve-SW4PN1KZRfz81tEV0rv3AnGyjkMkwo3koDc5SDXHGTOQd7nIG-z6N1D66WbTP8keTQ-A3wFfpvO26gH47R5wnJSVc1KJpq8A9IO6d781i8uZenH_5dmmq10zIS7NOHPJ_8x_x3ErLPA</recordid><startdate>20200811</startdate><enddate>20200811</enddate><creator>Taylor, Nick P.</creator><creator>Kim, Hyunyeon</creator><creator>Krause, Andrew L.</creator><creator>Van Gorder, Robert A.</creator><general>Springer US</general><general>Springer Nature</general><general>Springer Nature B.V</general><scope>AOWDO</scope><scope>BLEPL</scope><scope>DTL</scope><scope>NPM</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7SS</scope><scope>7TK</scope><scope>JQ2</scope><scope>K9.</scope><scope>7X8</scope><orcidid>https://orcid.org/0000-0002-8506-3961</orcidid><orcidid>https://orcid.org/0000-0001-9638-7278</orcidid></search><sort><creationdate>20200811</creationdate><title>A Non-local Cross-Diffusion Model of Population Dynamics I: Emergent Spatial and Spatiotemporal Patterns</title><author>Taylor, Nick P. ; 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We first consider diffusive instabilities, determining that for directed motion along fecundity gradients, the model permits the Turing instability leading to colony formation and persistence provided there are three or more interacting species. We also prove that such patterning is not possible in the model under the Turing mechanism for two species under directed motion along fecundity gradients, confirming earlier findings in the literature. However, when the directed motion is not along fecundity gradients, for instance, if foraging or migration is sub-optimal relative to fecundity gradients, we find that very different colony structures can emerge. This generalization also permits colony formation for two interacting species. In the advection-dominated case, aggregation patterns are more broad and global in nature, due to the inherent non-local nature of the advection which permits directed motion over greater distances, whereas in the diffusion-dominated case, more highly localized patterns and colonies develop, owing to the localized nature of random diffusion. We also consider the interplay between Turing patterning and spatial heterogeneity in resources. We find that for small spatial variations, there will be a combination of Turing patterns and patterning due to spatial forcing from the resources, whereas for large resource variations, spatial or spatiotemporal patterning can be modified greatly from what is predicted on homogeneous domains. For each of these emergent behaviors, we outline the theoretical mechanism leading to colony formation and then provide numerical simulations to illustrate the results. 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subjects	Advection Agglomeration Biology Cell Biology Colonies Colonies & territories Computer simulation Diffusion Dispersal Fecundity Heterogeneity Life Sciences Life Sciences & Biomedicine Life Sciences & Biomedicine - Other Topics Mathematical & Computational Biology Mathematical and Computational Biology Mathematical models Mathematics Mathematics and Statistics Motion stability Original Paper Population dynamics Science & Technology Spatial heterogeneity Spatial variations Species
title	A Non-local Cross-Diffusion Model of Population Dynamics I: Emergent Spatial and Spatiotemporal Patterns
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