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Using ecosystem modeling for fisheries management

Using ecosystem modeling for fisheries management. Villy Christensen. IncoFish WP4 Workshop. Cape Town, September 2006. Are ecosystem models useful for fisheries management?. “One of those really smart quotes”.

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Using ecosystem modeling for fisheries management

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  1. Using ecosystem modeling for fisheries management Villy Christensen IncoFish WP4 Workshop Cape Town, September 2006

  2. Are ecosystem models useful for fisheries management?

  3. “One of those really smart quotes” “We believe the food web modelling approach is hopeless as an aid to formulating management advice; the number of parameters and assumptions required are enormous.” Hilborn and Walters (1992, p. 448)

  4. Willie asked the right question... • Why don’t the fish eat them all, dad?

  5. A key aspect of EwE modeling: • Prey behavior limits predation (foraging arena assumptions)

  6. Prey eaten Prey eaten Prey density Prey density Organisms are not chemicals! Ecological interactions are highly organized Reaction vat model Foraging arena model Prey behavior limits rate Predator handling limits rate Big effects from small changes in space/time scale

  7. Foraging arena Predator, P aVP Available prey, V v(B-V) vV Unavailable prey B-V v = behavioral exchange rate (‘vulnerability’); predator-prey specific;based on foraging arena theory (Walters and Juanes, 1993)

  8. Time predictions from an ecosystem model of the Georgia Strait, 1950-2000 With mass-action (Lotka-Volterra) interactions only: With foraging arena interactions:

  9. A critical parameter: vulnerability Top-down/bottom-up “control” & carrying capacity

  10. Predation mortality: effect of vulnerability V = = 2 Top-Down Bottom-up High v Low v Predicted predation mortality ‘Traditional’ Ecosim Ecopath baseline 0 Carrying capacity Predator abundance

  11. So how do we get estimates of carrying capacity? • Surveys • Assessments • Stock reduction analysis Numbers (x 1000) Blue whales Fin whales Year Year Christensen, LB, 2006

  12. Evaluation of simulations • Can the model • replicate historic trends? • make plausible extrapolations to novel situations?

  13. A proliferation of ecosystem modeling activities has in recent years produced many apparently credible models that fit historical data well and make reasonable policy predictions Fitting to time series: learning from ecosystem history

  14. E Bering Sea Aleutian Islands W&C GoAlaska E GoAlaska W Vancouver Island Hecate Strait British Columbia Shelf Strait of Georgia NE Pacific CN & ET Pacific NWHI, Hawaii Gulf of California Central Chile Bay of Quinte Oneida Lake Scotian Shelf Chesapeake Bay Tampa Bay S Brazil Bight Norwegian Sea North Sea Baltic S Benguela Gulf of Thailand South China Sea Ecosystems where EwE models have been tested using historical trend data

  15. Modeling process: fitting & drivers Formal estimation Fishing Ecosystem model (predation, competition, mediation, age structured) (Diet0) Log Likelihood Predicted C, B, Z, W, diets (Z0) (BCC/B0) Observed C,B,Z,W, diets Nutrient loading Habitat area Climate Search Judgmental evaluation Choice of parametersto include in final estimation (e.g., climate anomalies) Errorpattern recognition

  16. Fishing effort: Confounding of fishery, environment, and trophic effects: monk seals in NWHI Initial Ecosim runs: fishing & trophic interactions together could not explain monk seal decline. Predicted lobster recovery 1970 2000 Satellite chlorophyll data indicate persistent ~40% decline in primary production around 1990. ‘Explains’ both continued monk seal decline and persistent low lobster abundance Low Chl

  17. Are seals causing fish declines in the Georgia Strait?Is it fishing? Is it environ-mental change?Or, is it all three? 1950 2000 1950 2000

  18. Strait of Georgia • EwE PP & Index of Fraser River runoff (March-April salinity at two measuring stations) Dave Preikshot, UBC FC

  19. BC Shelf biomass changes Dave Preikshot, UBC FC

  20. BC shelf: Upwelling index in May, June, and July. ≥10 year period Dave Preikshot, UBC FC

  21. Northeast Pacific biomass changes Dave Preikshot, UBC FC

  22. Northeast Pacific: PDO index (Pacific Decadal Oscillation), April to July. 50 year period Dave Preikshot, UBC FC

  23. Why have Steller sea lions declined? Guenette, Heymans, Christensen & Trites (CJFAS Nov 2006)

  24. Fishing Fishing Predation Predation 40,000 Competitive Interactions Competitive Interactions 30,000 Abundance 20,000 10,000 Ocean Climate Change 0 1960 1980 2000 Alaska Aleutian Islands Guénette, Heymans, Christensen & Trites (MS)

  25. General finding: multiple factors impact ecosystem resources (in all but the easiest cases)

  26. Evaluating trends • Fishing pressure • Trophic impact, including competition • Environmental impact • Nutrient loading As a rule: All of the above contribute

  27. Are we finally able to develop useful predictive models for ecosystem management? • It’s beginning to look like it; • We can with some credibility describe agents of mortality and trophic interdependencies; • Evaluation of relative impact of fisheries and environmental factors is progressing; • As a rule we need to invoke fisheries and environmental drivers to fit models. • When we have a modelthat can replicate development over time we can (with some confidence) use it for ecosystem-based policy exploration.

  28. Report card: Using models to address ecosystem management questions

  29. Modeling report card (cont.)

  30. So are ecosystem models actually used for fisheries management?

  31. Use of EM for fisheries management • Multispecies models • Estimating predation mortality for stock assessment; • Limit harvest of prey species to meet consumer demands; • Impact of changing mesh size, North Sea roundfish; • Minke whale and harp seal culling? • Environmental Impact Assessment (EIA), Alaska groundfish; • Target species response to TACs, Bering Sea.

  32. Use of EM for fisheries management • EwE • Evaluate impact of shrimp trawling, GoCalifornia; • Evaluate impact of bycatch, GoCalifornia; • Evaluate impact of predators on shrimp, GoMexico; • Demonstrate ecological role of species, GoMexico; • Impact of proposed fisheries interventions, Namibia? • EIA of proposed fisheries interventions, Bering Sea; • EIA of alternative TAC’s, Bering Sea and GoAlaska; • Target species response to TACs, Bering Sea • Closed area sizing, Great Barrier Reef, Australia • Valuation of cormorant impact, Ortobello, Italy • South Africa pelagic fisheries: in progress.

  33. So why aren’t ecosystem models used more for management? • Lack of experience using ecosystem models for predictive purposes; • Ecosystem modeling is for strategic management, and supplements the tactical single species assessment; • Fisheries management process is trapped in tactical management; • Strategic decisions are virtually non-existing.

  34. We need longer-term data than typical in assessments to avoid shifting baselines, e.g., 1950-present; Data mining is required; There is much more information out there: Catches, CPUE, w, … Assessments should be expanded back in time: Stock Reduction Analysis; Biggest information gaps for: Mid-TL forage fishes; Novel conditions (vampires in the basement) Estimates of mortality rates. Data gap for modeling

  35. Our empirical knowledge is limited • Habitat and environmental changes (including those caused by fishing) and intensive fishery removals are creating novel situations, which we can only handle with difficulty: • We do not to understand the ‘mechanics’ of ecological response well enough to be able to predict all important responses to these novel situations; • Make models one can play with;

  36. Our capability to provide advice about large-scale dynamics is limited • We cannot resolve uncertainty about how ecosystems change based on models and time-series data only;

  37. Predictive approaches are uncertain, for some obvious reasons • Lack of long-term monitoring data on non-target species and life stages; • Concentration of interaction effects (trophic, habitat) on early life stages (recruitment) that are difficult to monitor; • Confounding of fishery, environmental, and trophic effects in historical data; • Failure to anticipate new problems (‘vampires in the basement’) due to unpredictable changes in system structure, (exotic invasions, fisheries inventions); • Unpredictable pre-adaptations to habitat alterations.

  38. Ecosystem modeling for adaptive management requires a very different approach to assessment • Modelers must attempt to uncover alternative models that equally well explain historical data but imply different policy choices: • Environmental vs. fisheries vs. trophic effects; • Policy options would include diagnostic management experiments to distinguish between the alternative models: • Spatial closures to test recovery predictions; • Ecosystem modification to test trophic interaction effects.

  39. Models are not like religion • you can have more than one

  40. The new Ecopath with Ecosim • Four year project funded through Lenfest Ocean Program • Lenfest Ocean Futures Project: • New generation of EwE to be released Sep 07 • Single-player game version 2008 • Multi-player game version 2009 • Customized versions facilitated • User Ownership

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