The mechanisms of interference competition:Two experiments on foraging waders

Models of population dynamics that include interference competition have often been applied to foraging waders and less so to other foragers, even though these models are, in principle, generally applicable. At present, however, it is still unclear whether interference competition is of importance f...

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Bibliographic Details
Published in:Behavioral Ecology
Main Authors: Vahl, Wouter, van der Meer, J, van Dullemen, D, Piersma, Theun, Weissing, Franz
Format: Article in Journal/Newspaper
Language:English
Published: 2005
Subjects:
Arenaria interpres
behavioral mechanisms
Calidris canutus
density dependence
exploitation competition
social dominance
TURNSTONE ARENARIA-INTERPRES
KNOTS CALIDRIS-CANUTUS
GROUP-SIZE
SPATIAL-DISTRIBUTION
FUNCTIONAL-RESPONSE
WADDEN SEA
VIGILANCE
FOOD
SHOREBIRDS
DOMINANCE
Red Knot
Ruddy Turnstone
Online Access:https://hdl.handle.net/11370/e32651bb-5467-45bd-9d7e-ba74b21b8fd4
https://research.rug.nl/en/publications/e32651bb-5467-45bd-9d7e-ba74b21b8fd4
https://doi.org/10.1093/beheco/ari073
https://pure.rug.nl/ws/files/6688377/2005BehavEcolVahl2.pdf
Description
Summary:Models of population dynamics that include interference competition have often been applied to foraging waders and less so to other foragers, even though these models are, in principle, generally applicable. At present, however, it is still unclear whether interference competition is of importance for foraging waders. To support this idea experimental evidence and knowledge of the mechanisms underlying interference effects are required. We experimentally determined the relationship between forager density and foraging success in two wader species: the red knot (Calidris canutus) and the ruddy turnstone (Arenaria interpres). With each of the two species, we conducted an experiment consisting of 300 one-min trials. In these trials we scored the behavior and the foraging success of focal individuals at specific combinations of bird and prey density. Irrespective of prey density, individuals of both species discovered fewer prey items at higher bird densities. Despite this, only in turnstones did intake rates decline with increasing bird density. Knots compensated for a lower prey-discovery rate by rejecting fewer prey items at higher bird densities. In knots, bird density had a complex, nonmonotonic effect on the time spent vigilant and searching. In turnstones the main effect of increased bird density was a reduction in the prey-encounter rate, that is, the reward per unit search time. Effects on the time spent vigilant and the time spent searching were less pronounced than in knots. Thus, the mechanistic basis of the effects of bird density was complex for each of the two species and differed between them.

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