A bioenergetlics-based population dynamics model of Pacific herring (Clupea harengus pallasi) coupled to a lower trophic level nutrient-phytoplankton-zooplankton model: Description, calibration, and sensitivity analysis
Authored by Kenneth A Rose, Bernard A Megrey, Francisco E Werner, Robert A Klumb, Douglas E Hay, David L Eslinger, S Lan Smith
Date Published: 2007
DOI: 10.1016/j.ecolmodel.2006.08.020
Sponsors:
Asia Pacific Network (APN)
Global Ocean Ecosystem Dynamics Program (GLOBEC)
North Pacific Marine Science Organization (PICES)
Heiwa-Nakajima Foundation of Japan
Japan International Science and Technology Exchange Center
Platforms:
No platforms listed
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Abstract
We describe an approach to dynamically couple a fish bioenergetics-based
population dynamics model to the NEMURO lower trophic level
nutrient-phytoplankton-zooplankton model. The coupled models, denoted
NEMURO.FISH and configured for Pacific herring (Clupea harengus
pallasii) on the west coast of Vancouver island, are capable of
simulating the daily dynamics of the lower trophic levels and the daily
average weight and numbers of individual herring in each of 10 age
classes over multiple years. New recruits to the herring population are
added each June based on either constant recruitment or dynamic
recruitment generated from an environmental Ricker spawner-recruitment
relationship. The dynamics of the three zooplankton groups in the NEMURO
model determine the consumption rate of the herring; herring consumption
affects the zooplankton, and egestion and excretion contribute to the
nitrogen dynamics. NEMURO was previously calibrated to field data for
the West Coast Vancouver Island. Thirty-year simulations of herring
growth and population dynamics were performed that used repeated
environmental conditions for the lower trophic levels of NEMURO and
historical environmental variables for the herring spawner-recruit
relationship. Herring dynamics were calibrated to the west coast of
Vancouver Island such that the coupled models reasonably duplicated
observed herring weights-at-age and total herring biomass. Additional
30-year simulations under constant recruitment with herring coupled and
uncoupled from NEMURO clearly showed the effects of the feedback
mechanism between the two models and also showed that herring have small
to moderate effects on their prey. Monte Carlo uncertainty analysis
showed the importance of feeding- and respiration-related parameters to
predicted individual and population herring growth. The utility of the
NEMURO.FISH framework for improving our understanding of climate change
effects on marine ecosystem dynamics is discussed. (c) 2006 Elsevier
B.V. All rights reserved.
Tags
Individual-based model
Spatially explicit
Interannual variability
Ecosystem
model
Marine ecosystem
Larval fish
Early-life history
Vancouver-island
Somatic energy content
Northeast pacific