Population-level consequences of spatially heterogeneous exposure to heavy metals in soil: An individual-based model of springtails
Authored by Volker Grimm, Valery E Forbes, Mattia Meli, Annemette Palmqvist, Apolline Auclerc
Date Published: 2013
DOI: 10.1016/j.ecolmodel.2012.11.010
Sponsors:
European Union
Platforms:
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Model Documentation:
ODD
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Mathematical description
Model Code URLs:
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Abstract
Contamination of soil with toxic heavy metals poses a major threat to
the environment and human health. Anthropogenic sources include smelting
of ores, municipal wastes, fertilizers, and pesticides. In assessing
soil quality and the environmental and ecological risk of contamination
with heavy metals, often homogeneous contamination of the soil is
assumed. However, soils are very heterogeneous environments.
Consequently, both contamination and the response of soil organisms can
be assumed to be heterogeneous. This might have consequences for the
exposure of soil organisms and for the extrapolation of risk from the
individual to the population level. Therefore, to explore how soil
contamination of different spatial heterogeneity affects population
dynamics of soil invertebrates, we developed a spatially explicit
individual-based model of the springtail, Folsomia candida, a standard
test species for ecotoxicological risk assessment. In the model, individuals were assumed to sense and avoid contaminated habitat with a
certain probability that depends on contamination level. Avoidance of
contaminated areas thus influenced the individuals' movement and
feeding, their exposure, and in turn all other biological processes
underlying population dynamics. Model rules and parameters were based on
data from the literature, or were determined via pattern-oriented
modelling. The model correctly predicted several patterns that were not
used for model design and calibration. Simulation results showed that
the ability of the individuals to detect and avoid the toxicant, combined with the presence of clean habitat patches which act as
``refuges{''}, made equilibrium population size due to toxic effects
less sensitive to increases in toxicant concentration. Additionally, the
level of heterogeneity among patches of soil (i.e. the difference in
concentration) was important: at the same average concentration, a
homogeneously contaminated scenario was the least favourable habitat, while higher levels of heterogeneity corresponded to higher population
growth rate and equilibrium size. Our model can thus be used as a tool
for extrapolating from short-term effects at the individual level to
long-term effects at the population level under more realistic
conditions. It can thus be used to develop and extrapolate from standard
ecotoxicological tests in the laboratory to ecological risk assessments.
(C) 2012 Elsevier B.V. All rights reserved.
Tags
Dynamics
contamination
Protocol
Toxicity
Copper
Zinc
Lead
Avoidance
Folsomia-candida collembola
Isotomidae