Hydrology, habitat change and population demography: an individual-based model for the endangered Cape Sable seaside sparrow Ammodramus maritimus mirabilis
Authored by B D Elderd, M Philip Nott
Date Published: 2008
DOI: 10.1111/j.1365-2664.2007.01369.x
Sponsors:
United States National Science Foundation (NSF)
Platforms:
No platforms listed
Model Documentation:
Other Narrative
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Model Code URLs:
Model code not found
Abstract
1. Habitat destruction and fragmentation have led to precipitous
declines in a number of species of concern. For these species, traditional models that group individuals into age or stage cohorts may
not accurately capture the stochasticity associated with small
populations. Additionally, traditional models do not explicitly
incorporate landscape-level structure, which becomes increasingly
important at small population sizes. Thus, for declining species, spatially explicit individual-based models (SEIBM) can be used to
understand both population demography and the impacts of habitat
destruction, and to guide management practices to increase the chances
of species survival.
2. To gauge the impacts of changes in habitat and also demographic rates
on a US endangered species, we constructed an SEIBM for the Cape Sable
seaside sparrow (Ammodramus maritimus mirabilis Howell) of the South
Florida Everglades. The model simulates temporal and spatial dynamics of
individual sparrows using local GIS-based topography, vegetation and
hydrology along with behavioural and demographic rates derived from
field studies.
3. When adult mortality and, to a lesser extent, juvenile mortality were
increased in model simulations, there was an increase in extinction risk
and a decrease in population size, whereas changes in number of clutches
or female mating range had little impact. In contrast to the effects of
simulating changes in mortality rates, simulated landscape-level changes
(increasing water levels or decreasing habitat availability) were
associated with dramatic population declines and increases in extinction
risk. The sparrow appears to be particularly sensitive to the loss of
higher-elevation breeding habitat. These results highlight the
importance of proper water- and land-use management in assuring the
species' survival.
4. Synthesis and applications. Although changes in demographic rates
affect population growth and are often the focus of conservation
efforts, changes in habitat structure can also dramatically alter
population viability. When both landscape-level and demographic data are
available, spatially explicit models are particularly advantageous. Not
only do they allow researchers and resource managers to prioritize areas
for habitat restoration and species management, but they can also be
used to help focus future research efforts.
Tags
behavior
Dynamics
Fragmentation
Landscape structure
Consequences
Vegetation
Disturbance
Red-cockaded woodpecker
Everglades restoration
Picoides-borealis