Modelling the effect of buoyancy on the transport of anchovy (Engraulis capensis) eggs from spawning to nursery grounds in the southern Benguela: an IBM approach
Authored by C Mullon, C Parada, der Lingen CD Van, P Penven
Date Published: 2003
DOI: 10.1046/j.1365-2419.2003.00235.x
Sponsors:
Institut de Recherche pour le Développement (IRD)
Platforms:
No platforms listed
Model Documentation:
Other Narrative
Flow charts
Mathematical description
Model Code URLs:
Model code not found
Abstract
An individual-based model (IBM) was used to investigate the effects of
physical and biological variables on the transport via a jet current of
anchovy (Engraulis capensis ) eggs from spawning to the nursery grounds
in the southern Benguela ecosystem. As transport of eggs and early
larvae is considered to be one of the major factors impacting on anchovy
recruitment success, this approach may be useful to understand further
the recruitment variability in this economically and ecologically
important species. By coupling the IBM to a 3D hydrodynamic model of the
region called Plume, and by varying parameters such as the spatial and
temporal location of spawning, particle buoyancy, and the depth range
over which particles were released, we could assess the influences of
these parameters on transport success. A sensitivity analysis using a
General Linear Model identified the primary determinants of transport
success in the various experimental simulations, and model outputs were
examined and compared with patterns observed in field studies. Model
outputs compared well with observed patterns of vertical and horizontal
egg distribution. Particle buoyancy and area of particle release were
the major single determinants of transport success, with an egg density
of 1.025 g cm(-3) maximizing average particle transport success and the
western Agulhas Bank being the most successful spawning area. This IBM
may be useful as a generic prototype for other upwelling ecosystems.
Tags
patterns
Africa
Recruitment
System
Vertical-distribution
Larvae
Pelagic fish
Ichthyoplankton
Jet current