Dynamics of age-structured predator-prey populations in space: Asymmetrical effects of mobility in juvenile and adult predators
Authored by WG Wilson, AM DeRoos, E McCauley
Date Published: 1996
DOI: 10.2307/3546342
Sponsors:
National Science and Engineering Research Council of Canada (NSERC)
Netherlands Organization for Scientific Research (NWO)
Platforms:
No platforms listed
Model Documentation:
Other Narrative
Mathematical description
Model Code URLs:
Model code not found
Abstract
In many natural predator-prey systems, there are differences in mobility
between individual predators and prey. In this paper, we use
individual-based models to examine how differences in mobility of
age-structured predator populations affect the spatial and temporal
dynamics of predator-prey populations. Predators and prey in our model
do not possess any behavioral rules for aggregation, and spatial
heterogeneity is internally generated from the interaction among
individuals (i.e. populations are not externally subdivided into
patches). We show that differential mobility by juvenile and adult
predators can have an asymmetrical effect on stability when prey
mobility is relatively limited. Increasing the mobility of adult
predators destabilizes predator-prey dynamics, while changing juvenile
mobility does not. We also investigate stage-structured dispersal by
predators and show that, contrary to general conclusions from
metapopulation theory, widespread dispersal of predator offspring can
actually stabilize dynamics and lead to novel patterns of spatial
organization of predator and prey populations. With limited mobility of
individuals and local offspring production, stability arises because of
the asynchrony of dynamics among many different regions of the lattice.
Dispersing predator offspring (i.e. decoupling local recruitment from
local predator-prey interactions) produces stability of `'local''
regions and large-scale spatial patterning.
Tags
movements
pattern
Dispersal
stability
Environments
Diffusion-model
Landscapes
Spatial scales
Daphnia-pulex
Host-parasitoid systems