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Socio-Economic Instability and the Scaling of Energy Use with Population SizeCurrent demographics suggest future energy supplies will be inadequate to slow human population growthPopulation stability, cooperation, and the invasibility of the human speciesA bioenergetic framework for the temperature dependence of trophic interactions.Temperature alters food web body-size structure.Crossing regimes of temperature dependence in animal movement.The body-size dependence of mutual interference.Coexistence via resource partitioning fails to generate an increase in community functionPredators catalyze an increase in chloroviruses by foraging on the symbiotic hosts of zoochlorellae.The rate-size trade-off structures intraspecific variation in Daphnia ambigua life history parameters.Energetic inequivalence in eusocial insect colonies.Large but uneven reduction in fish size across species in relation to changing sea temperatures.The combined effects of reactant kinetics and enzyme stability explain the temperature dependence of metabolic rates.How fast is fast? Eco-evolutionary dynamics and rates of change in populations and phenotypes.Gillespie eco-evolutionary models (GEMs) reveal the role of heritable trait variation in eco-evolutionary dynamicsWhat if fertility decline is not permanent? The need for an evolutionarily informed approach to understanding low fertilityRemarkable size-spectra stability in a marine system undergoing massive invasion.Population-level scaling of avian migration speed with body size and migration distance for powered fliers.Ecological Pleiotropy Suppresses the Dynamic Feedback Generated by a Rapidly Changing Trait.Beyond body mass: how prey traits improve predictions of functional response parameters.Life history traits and functional processes generate multiple pathways to ecological stability.The body size dependence of trophic cascades.Size-dependent Catalysis of Chlorovirus Population Growth by A Messy Feeding Predator.A dynamic explanation of size-density scaling in carnivores.Predation changes the shape of thermal performance curves for population growth rate.Spring phenology of ecological productivity contributes to the use of looped migration strategies by birds.Increased temperature variation poses a greater risk to species than climate warming.A cascade of evolutionary change alters consumer-resource dynamics and ecosystem function.Predators modify the temperature dependence of life-history trade-offsMetabolic rate links density to demography in Tetrahymena pyriformisTrade-offs between morphology and thermal niches mediate adaptation in response to competing selective pressuresHabitat, latitude and body mass influence the temperature dependence of metabolic rateEcological pleiotropy and indirect effects alter the potential for evolutionary rescueOpportunities for behavioral rescue under rapid environmental changeFunctional responses are maximized at intermediate temperatures
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P50
description
onderzoeker
@nl
researcher
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հետազոտող
@hy
name
John P DeLong
@ast
John P DeLong
@en
John P DeLong
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John P DeLong
@nl
type
label
John P DeLong
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John P DeLong
@en
John P DeLong
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John P DeLong
@nl
prefLabel
John P DeLong
@ast
John P DeLong
@en
John P DeLong
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John P DeLong
@nl
P106
P21
P31
P496
0000-0003-0558-8213