about
The case for open preprints in biologySocial network analysis shows direct evidence for social transmission of tool use in wild chimpanzeesTen Simple Rules for Digital Data StorageA continuum of specialists and generalists in empirical communitiesMorphological and molecular evolution are not linked in Lamellodiscus (Plathyhelminthes, Monogenea)Resource availability affects the structure of a natural bacteria-bacteriophage community.High-throughput sequencing: a roadmap toward community ecologyTrophic complementarity drives the biodiversity-ecosystem functioning relationship in food webs.Dispersal and spatial heterogeneity allow coexistence between enemies and protective mutualists.An a posteriori measure of network modularity.Lack of quantitative training among early-career ecologists: a survey of the problem and potential solutionsA conceptual framework for the evolution of ecological specialisation.The spread of a novel behavior in wild chimpanzees: New insights into the ape cultural mind.Terminal investment induced by a bacteriophage in a rhizosphere bacterium.Linear filtering reveals false negatives in species interaction data.Phage-bacteria infection networks.Network structure and local adaptation in co-evolving bacteria-phage interactions.When is an ecological network complex? Connectance drives degree distribution and emerging network properties.Facultative and obligate parasite communities exhibit different network properties.Trophic network structure emerges through antagonistic coevolution in temporally varying environments.Identifying a common backbone of interactions underlying food webs from different ecosystems.Interactions between immunocompetence, somatic condition and parasitism in the chubLeuciscus cephalusin early springSynthetic datasets and community tools for the rapid testing of ecological hypothesesConnecting people and ideas from around the world: global innovation platforms for next-generation ecology and beyondInferring food web structure from predator-prey body size relationshipsHosts, parasites and their interactions respond to different climatic variablesSimulations of biomass dynamics in community food webspaco: implementing Procrustean Approach to Cophylogeny in RDescribe, understand and predict: why do we need networks in ecology?Temperature and trophic structure are driving microbial productivity along a biogeographical gradientHow ecological networks evolveEvolutionary Ecology of Specialisationmangal - making ecological network analysis simpleThe structure of probabilistic networksThe structure of probabilistic networksBeyond species: why ecological interaction networks vary through space and timeBiMat : a MATLAB package to facilitate the analysis of bipartite networksConnecting people and ideas from around the world: global innovation platforms for next-generation ecology and beyondmangal - making ecological network analysis simpleUsing neutral theory to reveal the contribution of meta-community processes to assembly in complex landscapes
P50
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P50
description
hulumtuese
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հետազոտող
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name
Timothée Poisot
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Timothée Poisot
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Timothée Poisot
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Timothée Poisot
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Timothée Poisot
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Timothée Poisot
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Timothée Poisot
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Timothée Poisot
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Timothée Poisot
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Timothée Poisot
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Timothée Poisot
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Timothée Poisot
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Timothée Poisot
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Timothée Poisot
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Timothée Poisot
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P106
P21
P31
P496
0000-0002-0735-5184