Controlling invasive fish in fluctuating environments: Model analysis of common carp (Cyprinus carpio) in a shallow lake

Controlling invasive fish in fluctuating environments: Model analysis of common carp (Cyprinus carpio) in a shallow lake

Climate change can act to facilitate or inhibit invasions of non‐native species. Here, we address the influence of climate change on control of non‐native common carp (hereafter, carp), a species recognized as one of the “world's worst” invaders across the globe. Control of this species is exce...

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Bibliographic Details
Published in:Ecosphere (Washington, D.C) D.C), 2022-05, Vol.13 (5), p.n/a
Main Authors: Pearson, James B., Bellmore, J. Ryan, Dunham, Jason B.
Format: Article
Language:eng
Subjects:
Aquatic ecosystems
Biodiversity
Carp
CarpMOD
Climate change
common carp
Demography
Density dependence
ecological modeling
Habitats
Hydrologic regime
hydrologic variability
Indigenous species
Influence
Invasive fish
Invasive species
Lakes
Native species
Nonnative species
pest control
Population
Population growth
Precipitation
Rivers
shallow lake
wetland management
Wildlife sanctuaries
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Summary:Climate change can act to facilitate or inhibit invasions of non‐native species. Here, we address the influence of climate change on control of non‐native common carp (hereafter, carp), a species recognized as one of the “world's worst” invaders across the globe. Control of this species is exceedingly difficult, as it exhibits rapid population growth and compensatory density dependence. In many locations where carp have invaded, however, climate change is altering hydrologic regimes and may influence population demography and efficacy of human control efforts. To further evaluate these processes, we employed a modified version of an age‐based population model (CarpMOD), to investigate how hydrologic variability (change in lake area) influences carp population dynamics and control efforts in Malheur Lake, southeastern Oregon, USA. We explored how changes in lake area influence carp populations under three control scenarios: (1) no carp removal, (2) carp removal during low water years, and (3) carp removal during all years. Lake area fluctuations strongly influenced carp populations and the efficacy of carp control. Modeled carp biomass peaked when the lake transitioned from high‐to‐low levels, and carp biomass declined when lake area transitioned from low‐to‐high. Removing carp during low water periods—when fish were concentrated into a smaller area—reduced carp populations almost as much as removing carp every year. Furthermore, the effectiveness of control efforts increased with the prevalence and severity of low lake conditions (longer durations of very low lake area). These simulations suggest that a drier climate may naturally decrease carp populations and make them easier to control. However, drier conditions may also negatively affect aquatic ecosystems and potentially have a greater impact than non‐native species themselves.
ISSN:2150-8925
2150-8925