The effect of landscape heterogeneity on the probability of patch colonization
Authored by RH Gardner, EJ Gustafson
Date Published: 1996
DOI: 10.2307/2265659
Sponsors:
United States Department of Energy (DOE)
United States National Science Foundation (NSF)
Ecological Research Division
Platforms:
Fortran
Model Documentation:
Other Narrative
Mathematical description
Model Code URLs:
Model code not found
Abstract
The effect of landscape heterogeneity on the dispersal of organisms
between habitat islands is poorly understood. Preferred pathways for
dispersal (i.e., corridors), as well as dispersal barriers, are
difficult to identify when the landscape matrix is composed of a complex
mixture of land cover types. We developed an individual-based dispersal
model to measure immigration and emigration rates between habitat
islands within heterogeneous landscapes. Dispersing individuals of a
model organism were simulated as self-avoiding random walkers (SAW)
traversing a digital land cover map, with each habitat type assigned a
priori a probability that the SAW would enter that habitat type. Each
individual began the dispersal process on a random site at the edge of a
deciduous forest patch and was allowed to move until it reached a
different deciduous forest patch. Visualization of the movement patterns
across the landscape was achieved by tabulating the frequency of
visitation of successful dispersers to each grid cell on the map. The
model was used to estimate the probabilities of disperser transfer
between patches by varying the a priori probabilities of movement into
each habitat type in order to: (1) estimate the effect of changing
landscape heterogeneity on the transfer probabilities, and (2) visualize
dispersal corridors and barriers as perceived by model organisms
operating by specific movement rules and at specific scales. The results
show that 89\% of the variability in dispersal success can be accounted
for by differences in the size and isolation of forest patches, with
closer and larger patches having significantly greater exchange of
dispersing organisms. However, changes in the heterogeneity of the
landscape matrix could significantly enhance or decrease emigration
success from an individual patch, depending on the landscape. Changes in
emigration success from an individual patch resulting from changes in
matrix heterogeneity were not predictable, and transfer rates between
patches were not symmetrical due to differences in the proximity of
neighboring patches, and differences in the funneling attributes of
certain landscape patterns. Visualizations showed that corridors are
often diffuse and difficult to identify from structural features of the
landscape. A wide range of organisms with differing movement
capabilities can be simulated using the approach presented to increase
our understanding of how landscape structure affects organism dispersal.
Tags
connectivity
models
Habitat fragmentation
Dispersal
biogeography
Population-dynamics
Environments
Metapopulation
dynamics
Organisms
Satellite species hypothesis