Surplus production dynamics in declining and recovering fish populations

Surplus production rates predicted by simple biomass dynamics models are generally expected to follow a simple dome-shaped pattern as population size changes and to show similar trajectories during population decline and recovery. Age-structured models, however, predict substantially lower surplus p...

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Bibliographic Details
Published in:Canadian journal of fisheries and aquatic sciences 2008-11, Vol.65 (11), p.2536-2551
Main Authors: Walters, Carl J, Hilborn, Ray, Christensen, Villy
Format: Article
Language:English
Subjects:
Agnatha. Pisces
Animal behavior
Animal populations
Animal, plant and microbial ecology
Applied ecology
Aquatic ecosystems
Aquatic sciences
Biological and medical sciences
Community structure
Distribution
Ecosystem models
Exploitation and management of natural biological resources (hunting, fishing and exploited populations survey, etc.)
Fecundity
Fish
Fish populations
Fundamental and applied biological sciences. Psychology
Growth
Marine
Population biology
Population decline
Population number
Vertebrates: general zoology, morphology, phylogeny, systematics, cytogenetics, geographical distribution
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Summary:Surplus production rates predicted by simple biomass dynamics models are generally expected to follow a simple dome-shaped pattern as population size changes and to show similar trajectories during population decline and recovery. Age-structured models, however, predict substantially lower surplus production rates during population recovery than during decline because of reduced mean fecundity, unless recruitment compensation is very strong. Ecosystem models like Ecosim predict more complex patterns, with reduced production during recoveries due to both age-structure effects and cultivation-depensation effects related to changes in competitor and predator abundances. Production-driven recoveries, where surplus production per biomass is higher during recovery than decline, are predicted in cases where there has been substantial change in overall ecosystem productivity or community structure. 110 case examples illustrate that simple, repeatable relationships between stock size and production are uncommon, and the most common pattern is production-driven change in stock size, where changes in production rate apparently independent of stock size then drive stock increase or decrease. We conclude that nonstationarity in productivity needs to be considered as part of population rebuilding and that empirical estimates of surplus production may provide insight in this process.
ISSN:0706-652X
1205-7533
DOI:10.1139/F08-170