A model of life cycle, connectivity and population stability of benthic macro-invertebrates in the North Sea/Baltic Sea transition zone
Authored by Jorgen Bendtsen, Jorgen L S Hansen
Date Published: 2013
DOI: 10.1016/j.ecolmodel.2013.07.012
Sponsors:
Danish Environmental Agency
Danish Strategic Science Foundation
Platforms:
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Model Documentation:
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Mathematical description
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Abstract
The life cycle of many benthic macro-invertebrates is characterised by a
planktonic life stage where larvae are transported by ocean currents and
mixing and after some time they reach a stage where they settle onto the
ocean bottom and, provided a suitable habitat is available, initiate
their benthic life stage as juvenile organisms and complete their life
cycle when they mature and spawn as adults. Such age-specific behaviour
is in general difficult to include in large scale ocean models unless
dispersal is considered on an individual basis, i.e. individual based
model coupled with a Lagrangian description of the flow field. However, here we address this issue in an Eulerian framework and develop and
apply a new life cycle and population dynamical model of benthic fauna
and implement the model in a high-resolution three-dimensional
circulation model of the North Sea/Baltic Sea transition zone. The model
explicitly describes specific life stages of the population and
considers the different processes affecting the organisms during their
life cycle, e.g. spawning, dispersion and settling. The model considers
different life stages of an idealised marine organism, representing a
typical benthic macro-invertebrate species in the area. Populations of
juvenile and adult benthic organisms are maintained by spawning, occurring regularly every spring, and subsequent settling of larvae. The
pelagic larval stages are simulated by a larval concentration
distribution function, i.e. discrete age-classes of the total larval
concentration, and age-specific physiological processes, as the onset of
their settling behaviour, is explicitly accounted for in the model.
Model simulations show, in general, a large connectivity between
habitats in the northern and southern part of the area but also that
self-recruitment is sufficient to sustain the two populations
independently. A sensitivity study were carried out with the spawning
rate as a control parameter and two non-trivial quasi-stationary steady
states of benthic biomass distributions were identified, characterised
by a high and low distribution of organisms in the area, respectively. A
stability diagram identifies a bifurcation point when the spawning rate
is reduced by 65\% and where lower spawning rates implies two different
stable equilibria. The existence of multiple quasi-stationary steady
states can be explained by the general circulation in the area: when
spawning into the surface layer takes place from recruitment areas close
to the North Sea where the out-flowing Baltic Sea surface water hinder
the southward transport of pelagic larvae. The existence of multiple
equilibria support the hypothesis of regime shifts in coupled
physical-biological systems where modest changes in critical processes
causes rapid and extensive structural changes in the ecosystem. Such
changes could occur if a system is close to a bifurcation point such
that small changes in critical internal biotic dynamics or in
environmental conditions force the system into a new equilibria, for
example due to hypoxia or changes in temperature or salinity. Finally, it is shown that model simulations of periods with hypoxic bottom water
masses reduces the total benthic biomass distribution in the area
significantly. (c) 2013 Elsevier B.V. All rights reserved.
Tags
Dynamics
Mortality
Recruitment
Consequences
Larval dispersal
Invertebrates
Baltic sea
Bottom water
Macrofauna
Basin