Relevant bibliographies by topics / Metapopulation dynamics

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  1. Journal articles
  2. Dissertations / Theses
  3. Books
  4. Book chapters
  5. Conference papers

Academic literature on the topic 'Metapopulation dynamics'

Author: Grafiati
Published: 4 June 2021
Last updated: 16 June 2025

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Journal articles on the topic "Metapopulation dynamics"

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Carroll, Emma L., Ailsa Hall, Morten Tange Olsen, Aubrie B. Onoufriou, Oscar E. Gaggiotti, and Debbie JF Russell. "Perturbation drives changing metapopulation dynamics in a top marine predator." Proceedings of the Royal Society B: Biological Sciences 287, no. 1928 (2020): 20200318. http://dx.doi.org/10.1098/rspb.2020.0318.

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Metapopulation theory assumes a balance between local decays/extinctions and local growth/new colonisations. Here we investigate whether recent population declines across part of the UK harbour seal range represent normal metapopulation dynamics or are indicative of perturbations potentially threatening the metapopulation viability, using 20 years of population trends, location tracking data ( n = 380), and UK-wide, multi-generational population genetic data ( n = 269). First, we use microsatellite data to show that two genetic groups previously identified are distinct metapopulations: northern and southern. Then, we characterize the northern metapopulation dynamics in two different periods, before and after the start of regional declines (pre-/peri-perturbation). We identify source–sink dynamics across the northern metapopulation, with two putative source populations apparently supporting three likely sink populations, and a recent metapopulation-wide disruption of migration coincident with the perturbation. The northern metapopulation appears to be in decay, highlighting that changes in local populations can lead to radical alterations in the overall metapopulation's persistence and dynamics.
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Wang, Shaopeng, Bart Haegeman, and Michel Loreau. "Dispersal and metapopulation stability." PeerJ 3 (October 1, 2015): e1295. http://dx.doi.org/10.7717/peerj.1295.

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Metapopulation dynamics are jointly regulated by local and spatial factors. These factors may affect the dynamics of local populations and of the entire metapopulation differently. Previous studies have shown that dispersal can stabilize local populations; however, as dispersal also tends to increase spatial synchrony, its net effect on metapopulation stability has been controversial. Here we present a simple metapopulation model to study how dispersal, in interaction with other spatial and local processes, affects the temporal variability of metapopulations in a stochastic environment. Our results show that in homogeneous metapopulations, the local stabilizing and spatial synchronizing effects of dispersal cancel each other out, such that dispersal has no effect on metapopulation variability. This result is robust to moderate heterogeneities in local and spatial parameters. When local and spatial dynamics exhibit high heterogeneities, however, dispersal can either stabilize or destabilize metapopulation dynamics through various mechanisms. Our findings have important theoretical and practical implications. We show that dispersal functions as a form of spatial intraspecific mutualism in metapopulation dynamics and that its effect on metapopulation stability is opposite to that of interspecific competition on local community stability. Our results also suggest that conservation corridors should be designed with appreciation of spatial heterogeneities in population dynamics in order to maximize metapopulation stability.
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Hanski, Ilkka. "Metapopulation dynamics." Nature 396, no. 6706 (1998): 41–49. http://dx.doi.org/10.1038/23876.

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Terui, Akira, Nobuo Ishiyama, Hirokazu Urabe, Satoru Ono, Jacques C. Finlay, and Futoshi Nakamura. "Metapopulation stability in branching river networks." Proceedings of the National Academy of Sciences 115, no. 26 (2018): E5963—E5969. http://dx.doi.org/10.1073/pnas.1800060115.

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Intraspecific population diversity (specifically, spatial asynchrony of population dynamics) is an essential component of metapopulation stability and persistence in nature. In 2D systems, theory predicts that metapopulation stability should increase with ecosystem size (or habitat network size): Larger ecosystems will harbor more diverse subpopulations with more stable aggregate dynamics. However, current theories developed in simplified landscapes may be inadequate to predict emergent properties of branching ecosystems, an overlooked but widespread habitat geometry. Here, we combine theory and analyses of a unique long-term dataset to show that a scale-invariant characteristic of fractal river networks, branching complexity (measured as branching probability), stabilizes watershed metapopulations. In riverine systems, each branch (i.e., tributary) exhibits distinctive ecological dynamics, and confluences serve as “merging” points of those branches. Hence, increased levels of branching complexity should confer a greater likelihood of integrating asynchronous dynamics over the landscape. We theoretically revealed that the stabilizing effect of branching complexity is a consequence of purely probabilistic processes in natural conditions, where within-branch synchrony exceeds among-branch synchrony. Contrary to current theories developed in 2D systems, metapopulation size (a variable closely related to ecosystem size) had vague effects on metapopulation stability. These theoretical predictions were supported by 18-y observations of fish populations across 31 watersheds: Our cross-watershed comparisons revealed consistent stabilizing effects of branching complexity on metapopulations of very different riverine fishes. A strong association between branching complexity and metapopulation stability is likely to be a pervasive feature of branching networks that strongly affects species persistence during rapid environmental changes.
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Yeakel, Justin D., Jean P. Gibert, Thilo Gross, Peter A. H. Westley, and Jonathan W. Moore. "Eco-evolutionary dynamics, density-dependent dispersal and collective behaviour: implications for salmon metapopulation robustness." Philosophical Transactions of the Royal Society B: Biological Sciences 373, no. 1746 (2018): 20170018. http://dx.doi.org/10.1098/rstb.2017.0018.

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The spatial dispersal of individuals plays an important role in the dynamics of populations, and is central to metapopulation theory. Dispersal provides connections within metapopulations, promoting demographic and evolutionary rescue, but may also introduce maladapted individuals, potentially lowering the fitness of recipient populations through introgression of heritable traits. To explore this dual nature of dispersal, we modify a well-established eco-evolutionary model of two locally adapted populations and their associated mean trait values, to examine recruiting salmon populations that are connected by density-dependent dispersal, consistent with collective migratory behaviour that promotes navigation. When the strength of collective behaviour is weak such that straying is effectively constant, we show that a low level of straying is associated with the highest gains in metapopulation robustness and that high straying serves to erode robustness. Moreover, we find that as the strength of collective behaviour increases, metapopulation robustness is enhanced, but this relationship depends on the rate at which individuals stray. Specifically, strong collective behaviour increases the presence of hidden low-density basins of attraction, which may serve to trap disturbed populations, and this is exacerbated by increased habitat heterogeneity. Taken as a whole, our findings suggest that density-dependent straying and collective migratory behaviour may help metapopulations, such as in salmon, thrive in dynamic landscapes. Given the pervasive eco-evolutionary impacts of dispersal on metapopulations, these findings have important ramifications for the conservation of salmon metapopulations facing both natural and anthropogenic contemporary disturbances. This article is part of the theme issue ‘Collective movement ecology’.
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Taylor, Caz M., and Richard J. Hall. "Metapopulation models for seasonally migratory animals." Biology Letters 8, no. 3 (2011): 477–80. http://dx.doi.org/10.1098/rsbl.2011.0916.

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Metapopulation models are widely used to study species that occupy patchily distributed habitat, but are rarely applied to migratory species, because of the difficulty of identifying demographically independent subpopulations. Here, we extend metapopulation theory to describe the directed seasonal movement of migratory populations between two sets of habitat patches, breeding and non-breeding, with potentially different colonization and extinction rates between patch types. By extending the classic metapopulation model, we show that migratory metapopulations will persist if the product of the two colonization rates exceeds the product of extinction rates. Further, we develop a spatially realistic migratory metapopulation model and derive a landscape metric—the migratory metapopulation capacity—that determines persistence. This new extension to metapopulation theory introduces an important tool for the management and conservation of migratory species and may also be applicable to model the dynamics of two host–parasite systems.
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SARDANYÉS, JOSEP, and ERNEST FONTICH. "ON THE METAPOPULATION DYNAMICS OF AUTOCATALYSIS: EXTINCTION TRANSIENTS RELATED TO GHOSTS." International Journal of Bifurcation and Chaos 20, no. 04 (2010): 1261–68. http://dx.doi.org/10.1142/s0218127410026460.

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One of the theoretical approaches to study spatially-extended ecosystems is given by metapopulation models, which consider fragmented populations inhabiting discrete patches linked by migration. Most of the metapopulation models assume exponential growth of the local populations and few works have explored the role of cooperation in fragmented ecosystems. In this letter, we study the dynamics and the bifurcation scenarios of a minimal, two-patch metapopulation Turing-like model given by nonlinear differential equations with an autocatalytic reaction term together with diffusion. We also analyze the extinction transients of the metapopulations focusing on the effect of coupling two local populations undergoing delayed transition phenomena due to ghost saddle remnants. We find that increasing diffusion rates enhance the delaying capacity of the ghosts. We finally propose the saddle remnant as a new class of transient generator mechanism for ecological systems.
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Anderson, B. J., H. R. Akçakaya, M. B. Araújo, et al. "Dynamics of range margins for metapopulations under climate change." Proceedings of the Royal Society B: Biological Sciences 276, no. 1661 (2009): 1415–20. http://dx.doi.org/10.1098/rspb.2008.1681.

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We link spatially explicit climate change predictions to a dynamic metapopulation model. Predictions of species' responses to climate change, incorporating metapopulation dynamics and elements of dispersal, allow us to explore the range margin dynamics for two lagomorphs of conservation concern. Although the lagomorphs have very different distribution patterns, shifts at the edge of the range were more pronounced than shifts in the overall metapopulation. For Romerolagus diazi (volcano rabbit), the lower elevation range limit shifted upslope by approximately 700 m. This reduced the area occupied by the metapopulation, as the mountain peak currently lacks suitable vegetation. For Lepus timidus (European mountain hare), we modelled the British metapopulation. Increasing the dispersive estimate caused the metapopulation to shift faster on the northern range margin (leading edge). By contrast, it caused the metapopulation to respond to climate change slower , rather than faster, on the southern range margin (trailing edge). The differential responses of the leading and trailing range margins and the relative sensitivity of range limits to climate change compared with that of the metapopulation centroid have important implications for where conservation monitoring should be targeted. Our study demonstrates the importance and possibility of moving from simple bioclimatic envelope models to second-generation models that incorporate both dynamic climate change and metapopulation dynamics.
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Eriksson, Anders, Federico Elías-Wolff, Bernhard Mehlig, and Andrea Manica. "The emergence of the rescue effect from explicit within- and between-patch dynamics in a metapopulation." Proceedings of the Royal Society B: Biological Sciences 281, no. 1780 (2014): 20133127. http://dx.doi.org/10.1098/rspb.2013.3127.

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Immigration can rescue local populations from extinction, helping to stabilize a metapopulation. Local population dynamics is important for determining the strength of this rescue effect, but the mechanistic link between local demographic parameters and the rescue effect at the metapopulation level has received very little attention by modellers. We develop an analytical framework that allows us to describe the emergence of the rescue effect from interacting local stochastic dynamics. We show this framework to be applicable to a wide range of spatial scales, providing a powerful and convenient alternative to individual-based models for making predictions concerning the fate of metapopulations. We show that the rescue effect plays an important role in minimizing the increase in local extinction probability associated with high demographic stochasticity, but its role is more limited in the case of high local environmental stochasticity of recruitment or survival. While most models postulate the rescue effect, our framework provides an explicit mechanistic link between local dynamics and the emergence of the rescue effect, and more generally the stability of the whole metapopulation.
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Junker, Marius, Martin Konvicka, Kamil Zimmermann, and Thomas Schmitt. "Gene-flow within a butterfly metapopulation: the marsh fritillary Euphydryas aurinia in western Bohemia (Czech Republic)." Journal of Insect Conservation 25, no. 4 (2021): 585–96. http://dx.doi.org/10.1007/s10841-021-00325-8.

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AbstractIn human-altered landscapes, species with specific habitat requirements tend to persist as metapopulations, forming colonies restricted to patches of suitable habitats, displaying mutually independent within-patch dynamics and interconnected by inter-colony movements of individuals. Despite intuitive appeal and both empirical and analytical evidence, metapopulations of only relatively few butterfly systems had been both monitored for multiple years to quantify metapopulation dynamics, and assayed from the point of view of population genetics. We used allozyme analysis to study the genetic make-up of a metapopulation of a declining and EU-protected butterfly, Euphydryas aurinia, inhabiting humid grasslands in western Czech Republic, and reanalysed previously published demography and dispersal data to interpret the patterns. For 497 colony x year visits to the 97 colonies known at that time, we found annual extinction and colonisation probabilities roughly equal to 4%. The genetic diversity within colonies was intermediate or high for all assessed parameters of population genetic diversity and hence higher than expected for such a habitat specialist species. All the standard genetic diversity measures were positively correlated to adult counts and colony areas, but the correlations were weak and rarely significant, probably due to the rapid within-colony population dynamics. Only very weak correlations applied to larval nests numbers. We conclude that the entirety of colonies forms a well-connected system for their majority. Especially in its core parts, we assume a metapopulation structure with a dynamic equilibrium between local extinction and recolonization. It is vital to conserve in particular these structures of large and interconnected colonies.Implications for insect conservation: Conservation measures should focus on considering more in depth the habitat requirements of E. aurinia for management plans and on stabilisation strategies for colonies, especially of peripheral ones, e.g. by habitat restoration.
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Dissertations / Theses on the topic "Metapopulation dynamics"

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Strevens, Chloë. "Insect metapopulation dynamics." Thesis, University of Oxford, 2010. http://ora.ox.ac.uk/objects/uuid:3e6c30d1-6c88-42d0-92d8-83c59f4269d2.

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Metapopulation ecology has developed to explain the population dynamics that occur in spatially structured landscapes. In this study, I combined an empirical laboratory approach, using metapopulation microcosms of Callosobruchus maculatus and its endospecific parasitoid Anisopteromalus calandrae, with mathematical population models in order to investigate several fundamental metapopulation processes. Population dynamics in these systems can be studied at two scales; the local patch-wise scale and the regional metapopulation scale. Here I demonstrate that in both homogeneous and heterogeneous landscapes knowledge of local scale demographic processes is necessary in order to understand regional metapopulation dynamics. The differences in the rate and net direction of dispersal between patches as a result of the permeability of the matrix in homogeneous systems and density-dependent dispersal in heterogeneous systems were also explored. Metapopulation dynamics rely on a balance between local extinctions and recolonisations. Therefore, increasing local mortality rates is likely to be detrimental to the persistence of the system. Here, the impact of several common harvesting strategies on the persistence of a host-parasitoid metapopulation was examined. Contrary to expectation I discovered that harvesting in these systems increased both local and regional population sizes. The increased population size as a result of increased mortality was explained in terms of a hydra effect, where harvesting relaxed density-dependence acting on local host populations. The results presented in this thesis are relevant for the monitoring, management and conservation of natural metapopulations and the development of sustainable harvesting strategies in structured landscapes.
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Valverde, Valdes Maria Teresa. "Metapopulation dynamics of Primula vulgaris." Thesis, Open University, 1995. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.283694.

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Ozgul, Seyfi Arpat. "Metapopulation dynamics of yellow-bellied marmots." [Gainesville, Fla.] : University of Florida, 2006. http://purl.fcla.edu/fcla/etd/UFE0013418.

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Padilla, Benjamin Juan. "Avian Metapopulation Dynamics in an Urbanizing Landscape." The Ohio State University, 2012. http://rave.ohiolink.edu/etdc/view?acc_num=osu1338227502.

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Telfer, Sandra E. "Dispersal and metapopulation dynamics in water vole populations." Thesis, University of Aberdeen, 2000. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.393236.

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Williams, Clair. "Metapopulation dynamics of the crested newt, Triturus cristatus." Thesis, University of Kent, 1999. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.314265.

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Strasser, Carly Ann. "Metapopulation dynamics of the softshell clam, Mya arenaria." Thesis, Massachusetts Institute of Technology, 2008. http://hdl.handle.net/1721.1/43818.

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Thesis (Ph. D.)--Joint Program in Biological Oceanography (Massachusetts Institute of Technology, Dept. of Biology; and the Woods Hole Oceanographic Institution), 2008.<br>Includes bibliographical references.<br>In this dissertation, I explored metapopulation dynamics and population connectivity, with a focus on the softshell clam, Mya arenaria. I first worked towards developing a method for using elemental signatures retained in the larval shell as a tag of natal habitat. I designed and implemented an experiment to determine whether existing methods commonly used for fishes would be applicable to bivalves. I found that the instrumentation and setup I used were not able to isolate and measure the first larval shell of M. arenaria. In concert with developing this method for bivalves, I reared larval M. arenaria in the laboratory under controlled conditions to understand the environmental and biological factors that may influence elemental signatures in shell. My results show that growth rate and age have significant effects on juvenile shell composition, and that temperature and salinity affect larval and juvenile shell composition in variable ways depending on the element evaluated. I also examined the regional patterns of diversity over the current distribution of M. arenaria using the mitochondrial gene, cytochrome oxidase I (COI). I found minimal variability across all populations sampled, suggesting a recent population expansion in the Northwest Atlantic. Finally, I employed theoretical approaches to understand patch dynamics in a two-patch metapopulation when one patch is of high quality and the other low quality. I developed a matrix metapopulation model and compared growth rate elasticity to patch parameters under variable migration scenarios. I then expanded the model to include stochastic disturbance. I found that in many cases, the spatial distribution of individuals within the metapopulation affects whether growth rate is most elastic to parameters in the good or bad patch.<br>by Carly A. Strasser.<br>Ph.D.
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Teissier, Yoann. "Metapopulation dynamics of dengue epidemics in French Polynesia." Thesis, Sorbonne Paris Cité, 2017. http://www.theses.fr/2017USPCB008.

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La dengue circule en Polynésie française sur un mode épidémique depuis plus de 35 ans. Néanmoins, en dépit de la taille relativement faible de la population de Polynésie française, la circulation de la dengue peut persister à de faibles niveaux pendant de nombreuses années. L’objectif de ce travail de thèse est de déterminer si l'épidémiologie de la dengue dans le système insulaire de la Polynésie française répond aux critères d’un contexte de métapopulation. Après avoir constitué une base de données regroupant les cas de dengue répertoriés sur les 35 dernières années, nous avons réalisé des analyses épidémiologiques descriptives et statistiques. Celles-ci ont révélé des disparités spatio-temporelles distinctes pour l’incidence de la dengue des archipels et des îles, mais la structure de l'épidémie globale à l’échelle de la Polynésie française pour un même sérotype ne semble pas être affectée. Les analyses de la métapopulation ont révélé l'incidence asynchrone de la dengue dans un grand nombre d’îles. Celle-ci s’observe plus particulièrement par la différence de dynamique de l’incidence entre les îles plus peuplées et celles ayant une population plus faible. La taille critique de la communauté nécessaire à la persistance de la dengue n’est même pas atteinte par la plus grande île de Polynésie Française, Tahiti. Ce résultat suggère que la dengue peut uniquement persister grâce à sa propagation d’île en île. L'incorporation de la connectivité des îles à travers des modèles de migration humaine dans un modèle mathématique a produit une dynamique de la dengue davantage en adéquation avec les données observées, que les tentatives de modélisation traitant la population dans son ensemble. Le modèle de la métapopulation a été capable de simuler la même dynamique que les cas de dengue observés pour l'épidémie et la transmission endémique qui a suivi pour la période de 2001 à 2008. Des analyses complémentaires sur la différenciation de l'incidence de la maladie et de l'infection seront probablement instructives pour affiner le modèle de métapopulation de l'épidémiologie de la dengue en Polynésie française<br>Dengue has been epidemic in French Polynesia for the past 35 years. Despite the relatively small population size in French Polynesia, dengue does not disappear and can persist at low levels for many years. In light of the large number of islands comprising French Polynesia, this thesis addresses the extent to which a metapopulation context may be the most appropriate to describe the epidemiology and persistence of dengue in this case. After compiling a database of dengue cases over the last 35 years, we used a number of descriptive and statistical epidemiological analyses that revealed distinct spatio-temporal disparity in dengue incidence for archipelago and islands. But the global structure of the epidemics of the same serotype were not affected. Metapopulation analyses revealed asynchronous dengue incidence among many of the islands and most notably larger islands lagged behind the smaller islands. The critical community size, which determines dengue persistence, was found to exceed even the largest island of Tahiti, suggesting that dengue can only exist by island-hopping. Incorporation of island connectedness through patterns of human migration into a mathematical model enabled a much better fit to the observed data than treating the population as a whole. The metapopulation model was able to capture to some extent the epidemic and low level transmission dynamics observed for the period of 2001-2008. Further analyses on differentiating incidence of disease and infection will likely prove informative for the metapopulation model of dengue epidemiology in French Polynesia
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Anderson, Sarah. "Metapopulation dynamics of the Garden Tiger Moth (Arctia caja)." Thesis, Open University, 2005. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.422000.

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Lloyd, Alun Lewis. "Mathematical models for spatial heterogeneity in population dynamics and epidemiology." Thesis, University of Oxford, 1996. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.337603.

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Books on the topic "Metapopulation dynamics"

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Spromberg, Julann A. Metapopulation dynamics as a model for toxicant impacts in patchy environments. Huxley College of Environmental Studies, Western Washington University, 1995.

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Greenberg, Cathryn H. Amphibians using isolated ephemeral ponds in Florida longleaf pine uplands, population and metapopulation dynamics: Final report. Florida Fish and Wildlife Conservation Commission, 2006.

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Metapopulation dynamics. Harcourt Brace Jovanovich, 1991.

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Metapopulation Dynamics: Emperical and Theoretical Investigations. Academic Pr, 1991.

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Metapopulation Dynamics: Empirical and Theoretical Investigations. Elsevier, 1991. http://dx.doi.org/10.1016/b978-0-12-284120-0.x5001-3.

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Macovsky, Louis M. The effects of toxicant related mortality upon metapopulation dynamics: A laboratory model. 1999.

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A System Dynamics Investigation of Genetic Drift and Translocation in the Red-Cockaded Woodpecker Metapopulation. Storming Media, 2003.

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Book chapters on the topic "Metapopulation dynamics"

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Nisbet, Roger M., Cheryl J. Briggs, William S. C. Gurney, William W. Murdoch, and Allan Stewart-Oaten. "Two-Patch Metapopulation Dynamics." In Lecture Notes in Biomathematics. Springer Berlin Heidelberg, 1993. http://dx.doi.org/10.1007/978-3-642-50155-5_10.

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Clark, James S. "Shifting Mosaic Metapopulation Dynamics." In Lecture Notes in Biomathematics. Springer Berlin Heidelberg, 1993. http://dx.doi.org/10.1007/978-3-642-50155-5_16.

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Hanski, Ilkka. "Habitat Destruction and Metapopulation Dynamics." In The Ecological Basis of Conservation. Springer US, 1997. http://dx.doi.org/10.1007/978-1-4615-6003-6_22.

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Schooley, Robert L., and Bradley J. Cosentino. "Metapopulation Dynamics of Wetland Species." In The Wetland Book. Springer Netherlands, 2016. http://dx.doi.org/10.1007/978-94-007-6172-8_57-3.

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Schooley, Robert L., and Bradley J. Cosentino. "Metapopulation Dynamics of Wetland Species." In The Wetland Book. Springer Netherlands, 2018. http://dx.doi.org/10.1007/978-90-481-9659-3_57.

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Buckley, P. A., and Randall Downer. "Modelling Metapopulation Dynamics for Single Species of Seabirds." In Wildlife 2001: Populations. Springer Netherlands, 1992. http://dx.doi.org/10.1007/978-94-011-2868-1_42.

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Burton, Jennifer L., Ewan Robinson, and Sheng Ye. "Spatially Explicit Agent-Based Model of Striped Newt Metapopulation Dynamics Under Precipitation and Forest Cover Scenarios." In Ecologist-Developed Spatially-Explicit Dynamic Landscape Models. Springer US, 2012. http://dx.doi.org/10.1007/978-1-4614-1257-1_5.

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Hanski, Ilkka. "The Theories of Island Biogeography and Metapopulation Dynamics Science Marches Forward, but the Legacy of Good Ideas Lasts for a Long Time." In The Theory of Island Biogeography Revisited, edited by Jonathan B. Losos and Robert E. Ricklefs. Princeton University Press, 2009. http://dx.doi.org/10.1515/9781400831920.186.

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Marquet, P. A., J. X. Velasco-Hernández, and J. E. Keymer. "Patch Dynamics, Habitat Degradation, and Space in Metapopulations." In How Landscapes Change. Springer Berlin Heidelberg, 2003. http://dx.doi.org/10.1007/978-3-662-05238-9_14.

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Smith, David, Maciej Boni, and Ramanan Laxminarayan. "Dynamics and control of antibiotic resistance in structured metapopulations." In Disease Evolution. American Mathematical Society, 2006. http://dx.doi.org/10.1090/dimacs/071/11.

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Conference papers on the topic "Metapopulation dynamics"

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Fabritius, Henna, Ari Jokinen, and Mar Cabeza. "Institutional fit in the maintenance of dynamic habitat networks for metapopulations." In 5th European Congress of Conservation Biology. Jyvaskyla University Open Science Centre, 2018. http://dx.doi.org/10.17011/conference/eccb2018/107786.

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Jianxin, Chen. "Metapopulation Model of the Banking Risk Contagion --- Dynamic Simulation Based on Cellular Automata." In 2010 International Conference on Computational and Information Sciences (ICCIS). IEEE, 2010. http://dx.doi.org/10.1109/iccis.2010.328.

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Wang, Stephanie. "A Novel Public Health Intervention Strategy for the Control of Infectious Disease Outbreaks Among Dynamic Metapopulation Networks." In ICBSP'20: 2020 5th International Conference on Biomedical Imaging, Signal Processing. ACM, 2020. http://dx.doi.org/10.1145/3436349.3436368.

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