Modelling secondary production in the Norwegian Sea with a fully coupled physical/primary production/individual-based Calanus finmarchicus model system
Authored by Geir Huse, Solfrid Saetre Hjollo, Webjorn Melle, Morten D Skogen
Date Published: 2012
DOI: 10.1080/17451000.2011.642805
Sponsors:
European Union
Norwegian Research Council (NRF)
Platforms:
No platforms listed
Model Documentation:
Other Narrative
Model Code URLs:
Model code not found
Abstract
The copepod Calanus finmarchicus is the dominant species of the
meso-zooplankton in the Norwegian Sea, and constitutes an important link
between the phytoplankton and the higher trophic levels in the Norwegian
Sea food chain. An individual-based model for C. finmarchicus, based on
super-individuals and evolving traits for behaviour, stages, etc., is
two-way coupled to the NORWegian ECOlogical Model system (NORWECOM). One
year of modelled C. finmarchicus spatial distribution, production and
biomass are found to represent observations reasonably well. High C.
finmarchicus abundance is found along the Norwegian shelf-break in the
early summer, while the overwintering population is found along the
slope and in the deeper Norwegian Sea basins. The timing of the spring
bloom is generally later than in the observations. Annual Norwegian Sea
production is found to be 29 million tonnes of carbon and a production
to biomass (P/B) ratio of 4.3 emerges. Sensitivity tests show that the
modelling system is robust to initial values of behavioural traits and
with regards to the number of super-individuals simulated given that
this is above about 50,000 individuals. Experiments with the model
system indicate that it provides a valuable tool for studies of
ecosystem responses to causative forces such as prey density or
overwintering population size. For example, introducing C. finmarchicus
food limitations reduces the stock dramatically, but on the other hand, a reduced stock may rebuild in one year under normal conditions.
Tags
Population-dynamics
North-sea
Marine ecosystems
Herring clupea-harengus
To-end models
Reproductive-biology
Frequency time-series
Seasonal dynamics
Oceanic model
Ice dynamics