Habitat heterogeneity and algal-grazer interactions in streams: Explorations with a spatially explicit model
Authored by K NelsonBaker, NL Poff
Date Published: 1997
DOI: 10.2307/1468256
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Mathematical description
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Abstract
We present results from a spatially explicit model that makes
predictions about how physical habitat heterogeneity mediates
algal-grazer interactions. We simulated the responses of mean algal
biomass and variability in the distribution of algae to 2 levels of
physical habitat heterogeneity (1 vs. 15 boulders) under 2 velocity
regimes (slow vs. fast riffles). Algal growth occurred locally in a
spatially explicit grid where local current was specified for each of
the 60 x 30 grid cells. Grazer movement and foraging were simulated
using an individual-based model, in which the direction and rate of
movement of individual grazers were determined at each time step in
relation to local current and algal standing crop. Model
parameterization was based on field observations, laboratory
experiments, and literature review.
In each of the 4 simulations, algae were first allowed to grow in the
absence of grazing to near carrying capacity. Neither habitat
heterogeneity nor riffle velocity regime had a significant effect on the
mean biomass or spatial variability of algae. Next, algae were exposed
to 3 simulated grazer densities and the subsequent effects on algal
biomass and patchiness were determined after prolonged contact. We
performed replicate simulation runs to allow statistical inferences to
be drawn about differential responses of algae to the various
`'treatments.'' As expected, mean algal biomass declined in proportion
to grazer density. Higher habitat heterogeneity resulted in reduced
algal biomass for low and intermediate grazer densities, but only in the
slow riffle. Otherwise, the effects of specified grazer densities did
not vary between slow and fast riffles. Variability in algal biomass
distribution was measured in 2 ways. First, a spatially explicit index
of relative patchiness showed a gradual increase under low grazer
density but a transient peak followed by decline under moderate and
intense grazing pressure, a pattern observed for both slow and fast
current regimes. In the slow riffle alone, heterogeneity and grazer
density interacted to influence algal patchiness. A second, non-spatially explicit index of variability in algal biomass, the
coefficient of variation, increased as grazer density increased
regardless of current regime. Higher variability in the distribution of
algal biomass tended to be associated with greater habitat
heterogeneity, especially in the slow riffle
The simulations suggested that spatial heterogeneity and ambient current
velocity regime mediate algal-grazer interactions. The extent to which
grazers crop biomass and create spatial variability in the distribution
of algal biomass may depend not only on grazer density but also on the
interaction between grazer density, physical habitat heterogeneity and
stream velocity. Given this complexity, empirical approaches to
understanding algal-grazer interactions in spatially and temporally
heterogeneous stream systems are likely to be greatly augmented by
modelling, which allows different environmental conditions and grazer
foraging behaviors to be simulated.
Tags
ecosystems
Community
Field
Insect
Abundance
Herbivores
Irradiance
Caddisfly population
Laboratory streams
Periphyton