Metapopulation dynamics on the brink of extinction
Authored by A Eriksson, F Elias-Wolff, B Mehlig
Date Published: 2013
DOI: 10.1016/j.tpb.2012.08.001
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Abstract
We analyse metapopulation dynamics in terms of an individual-based, stochastic model of a finite metapopulation. We suggest a new approach, using the number of patches in the population as a large parameter. This
approach does not require that the number of individuals per patch is
large, neither is it necessary to assume a time-scale separation between
local population dynamics and migration. Our approach makes it possible
to accurately describe the dynamics of metapopulations consisting of
many small patches. We focus on metapopulations on the brink of
extinction. We estimate the time to extinction and describe the most
likely path to extinction. We find that the logarithm of the time to
extinction is proportional to the product of two vectors, a vector
characterising the distribution of patch population sizes in the
quasi-steady state, and a vector related to Fisher's reproduction vector
that quantifies the sensitivity of the quasi-steady state distribution
to demographic fluctuations. We compare our analytical results to
stochastic simulations of the model, and discuss the range of validity
of the analytical expressions. By identifying fast and slow degrees of
freedom in the metapopulation dynamics, we show that the dynamics of
large metapopulations close to extinction is approximately described by
a deterministic equation originally proposed by Levins (1969). We were
able to compute the rates in Levins' equation in terms of the parameters
of our stochastic, individual-based model. It turns out, however, that
the interpretation of the dynamical variable depends strongly on the
intrinsic growth rate and carrying capacity of the patches. Only when
the local growth rate and the carrying capacity are large does the slow
variable correspond to the number of patches, as envisaged by Levins.
Last but not least, we discuss how our findings relate to other, widely
used metapopulation models. (C) 2012 Elsevier Inc. All rights reserved.
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models
Risk
Dispersal
Approximation
Population-dynamics
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Asymptotics