Two-way coupling versus one-way forcing of plankton and fish models to predict ecosystem changes in the Benguela
Authored by Yunne-Jai Shin, J G Field, M Travers, S Jennings, E Machu, J A Huggett, P M Cury
Date Published: 2009
DOI: 10.1016/j.ecolmodel.2009.08.016
Sponsors:
European Union
Platforms:
No platforms listed
Model Documentation:
Other Narrative
Flow charts
Mathematical description
Model Code URLs:
Model code not found
Abstract
`End-to-end' models have been adopted in an attempt to capture more of
the processes that influence the ecology of marine ecosystems and to
make system wide predictions of the effects of fishing and climate
change. Here, we develop an end-to-end model by coupling existing models
that describe the dynamics of low (ROMS-N(2)P(2)Z(2)D(2)) and high
trophic levels(OSMOSE). ROMS-N(2)P(2)Z(2)D(2) is a biogeochemical model
representing phytoplankton and zooplankton seasonal dynamics forced by
hydrodynamics in the Benguela upwelling ecosystem. OSMOSE is an
individual-based model representing the dynamics of several species of
fish, linked through opportunistic and size-based trophic interactions.
The models are coupled through a two-way size-based predation process.
Plankton provides prey for fish, and the effects of predation by fish on
the plankton are described by a plankton mortality term that is variable
in space and time. Using the end-to-end model, we compare the effects of
two-way coupling versus one-way forcing of the fish model with the
plankton biomass field. The fish-induced mortality on plankton is
temporally variable, in part explained by seasonal changes in fish
biomass. Inclusion of two-way feedback affects the seasonal dynamics of
plankton groups and usually reduces the amplitude of variation in
abundance (top-down effect). Forcing and coupling lead to different
predicted food web structures owing to changes in the dominant food
chain which is supported by plankton (bottom-up effect). Our comparisons
of one-way forcing and two-way coupling show how feedbacks may affect
abundance, food web structure and food web function and emphasise the
need to critically examine the consequences of different model
architectures when seeking to predict the effects of fishing and climate
change. (C) 2009 Elsevier B.V. All rights reserved.
Tags
Individual-based model
Population-models
Trophic interactions
Spawning frequency
Southern benguela
Reproductive-biology
Herring etrumeus-whiteheadi
Anchovy engraulis-capensis
African west-coast
Annual
consumption