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Physical forcing and the dynamics of the pelagic ecosystem in the eastern tropical Pacific: simulations with ENSO-scale and global-warming climate drivers
Watters, G.M.; Olson, R.J.; Francis, R.C.; Fiedler, P.C.; Polovina, J.J.; Reilly, S.B.; Aydin, K.Y.; Boggs, C.H.; Essington, T.E.; Walters, C.J.; Kitchell, J.F. (2003). Physical forcing and the dynamics of the pelagic ecosystem in the eastern tropical Pacific: simulations with ENSO-scale and global-warming climate drivers. Can. J. Fish. Aquat. Sci. 60(9): 1161-1175
In: Canadian Journal of Fisheries and Aquatic Sciences = Journal canadien des sciences halieutiques et aquatiques. National Research Council Canada: Ottawa. ISSN 0706-652X; e-ISSN 1205-7533, more
Peer reviewed article  

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Keywords
    Aquatic communities > Plankton > Phytoplankton
    Aquatic organisms > Marine organisms > Fish > Marine fish
    Climatic changes
    Ecosystems
    El Nino phenomena
    Interspecific relationships > Predation
    Models
    Oscillations > Southern oscillation
    Population functions > Mortality
    Population functions > Recruitment
    Trophic levels
    Marine/Coastal

Authors  Top 
  • Watters, G.M.
  • Olson, R.J.
  • Francis, R.C.
  • Fiedler, P.C.
  • Polovina, J.J.
  • Reilly, S.B.
  • Aydin, K.Y.
  • Boggs, C.H.
  • Essington, T.E.
  • Walters, C.J.
  • Kitchell, J.F.

Abstract
    We used a model of the pelagic ecosystem in the eastern tropical Pacific Ocean to explore how climate variation at El Niño - Southern Oscillation (ENSO) scales might affect animals at middle and upper trophic levels. We developed two physical-forcing scenarios: (1) physical effects on phytoplankton biomass and (2) simultaneous physical effects on phytoplankton biomass and predator recruitment. We simulated the effects of climate-anomaly pulses, climate cycles, and global warming. Pulses caused oscillations to propagate through the ecosystem; cycles affected the shapes of these oscillations; and warming caused trends. We concluded that biomass trajectories of single populations at middle and upper trophic levels cannot be used to detect bottom-up effects, that direct physical effects on predator recruitment can be the dominant source of interannual variability in pelagic ecosystems, that such direct effects may dampen top-down control by fisheries, and that predictions about the effects of climate change may be misleading if fishing mortality is not considered. Predictions from ecosystem models are sensitive to the relative strengths of indirect and direct physical effects on middle and upper trophic levels.

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