Biophysical modeling of survival and dispersal of Central and Eastern Baltic Sea flounder (Platichthys flesus) larvae

Biophysical modeling of survival and dispersal of Central and Eastern Baltic Sea flounder (Platichthys flesus) larvae

The period of larval drift into a suitable nursery area is considered to be of great significance for recruitment variability in flatfish. Here, a hydrodynamic model coupled with a Lagrangian particle tracking technique was utilized to study the drift from the first feeding larval stage until time o...

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Veröffentlicht in:Journal of sea research 2018-12, Vol.142, p.11-20
Hauptverfasser: Hinrichsen, H.-H., Petereit, C., von Dewitz, B., Haslob, H., Ustups, D., Florin, A.-B., Nissling, A.
Format: Artikel
Sprache:eng
Schlagworte:
Animal behavior
Animal reproduction
Basins
Coastal ecology
Coastal zone
Computer simulation
Dispersal
Drift
Dynamics
Fish
Fish and Aquacultural Science
Fisk- och akvakulturforskning
Flounder juvenile habitat suitability
Habitats
Hydrodynamic modeling
Hydrodynamics
Larvae
Larval drift
Marine fishes
Metamorphosis
Migration
Modelling
Nursery grounds
Ocean basins
Particle tracking
Platichthys flesus
Probability theory
Recruitment
Sediment type-related mortality
Simulation
Spawning
Survival
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container_end_page 20
container_issue
container_start_page 11
container_title Journal of sea research
container_volume 142
creator Hinrichsen, H.-H.
Petereit, C.
von Dewitz, B.
Haslob, H.
Ustups, D.
Florin, A.-B.
Nissling, A.
description The period of larval drift into a suitable nursery area is considered to be of great significance for recruitment variability in flatfish. Here, a hydrodynamic model coupled with a Lagrangian particle tracking technique was utilized to study the drift from the first feeding larval stage until time of settlement of Central and Eastern Baltic flounder (Platichthys flesus), originating from spawning in the Baltic Sea deep basins, the Arkona- and Bornholm basin (central Baltic Sea), and the Gdansk deep and Gotland basin (eastern Baltic Sea). We examined the spatio-temporal dynamics of the probability to settle in preferred nursery habitat by detailed drift model simulations. The study suggests that the majority of larvae (89% and 74% for Central- and Eastern Baltic flounder, respectively) drift towards coastal areas and settle at metamorphosis ≤20 km from a sandy habitat enabling further migration to a preferred nursery area, i.e. larval drift seems not to be a major bottleneck in recruitment of flounder spawning in the Baltic Sea deep basins. The drift model results suggest that Central Baltic flounder utilize nursery areas mainly in the central and western Baltic, and in the Kattegat, whereas Eastern Baltic flounder mainly utilize the coast in the central and eastern Baltic. Thus, the two stock components seem to use different nursery areas following settlement. Further, in accordance with the “nursery size hypothesis”, the model demonstrates that larvae from the Bornholm basin, utilizing areas with extensive distribution of preferred nursery habitat, display the highest relative successful transport to nursery grounds until settling (72% of successfully settled larvae), suggesting that spawning in the Bornholm Basin is of great importance for stock recruitment of deep basin spawning Baltic flounder. •Predominance of high connectivity between the eastern Baltic flounder nursery grounds for the juvenile stage•Two flounder stock components as separate subpopulations utilize different settlement areas•Traditional sampling methodology unable to resolve spatial juvenile distribution patterns without considering flow dynamics•Spatio-temporal variability of juvenile flounder habitat and density of settled juveniles•Additional habitat indicator: habitat availability for successful juvenile settlement of Baltic flounder
doi_str_mv 10.1016/j.seares.2018.09.004
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Here, a hydrodynamic model coupled with a Lagrangian particle tracking technique was utilized to study the drift from the first feeding larval stage until time of settlement of Central and Eastern Baltic flounder (Platichthys flesus), originating from spawning in the Baltic Sea deep basins, the Arkona- and Bornholm basin (central Baltic Sea), and the Gdansk deep and Gotland basin (eastern Baltic Sea). We examined the spatio-temporal dynamics of the probability to settle in preferred nursery habitat by detailed drift model simulations. The study suggests that the majority of larvae (89% and 74% for Central- and Eastern Baltic flounder, respectively) drift towards coastal areas and settle at metamorphosis ≤20 km from a sandy habitat enabling further migration to a preferred nursery area, i.e. larval drift seems not to be a major bottleneck in recruitment of flounder spawning in the Baltic Sea deep basins. The drift model results suggest that Central Baltic flounder utilize nursery areas mainly in the central and western Baltic, and in the Kattegat, whereas Eastern Baltic flounder mainly utilize the coast in the central and eastern Baltic. Thus, the two stock components seem to use different nursery areas following settlement. 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source Elsevier ScienceDirect Journals
subjects Animal behavior
Animal reproduction
Basins
Coastal ecology
Coastal zone
Computer simulation
Dispersal
Drift
Dynamics
Fish
Fish and Aquacultural Science
Fisk- och akvakulturforskning
Flounder juvenile habitat suitability
Habitats
Hydrodynamic modeling
Hydrodynamics
Larvae
Larval drift
Marine fishes
Metamorphosis
Migration
Modelling
Nursery grounds
Ocean basins
Particle tracking
Platichthys flesus
Probability theory
Recruitment
Sediment type-related mortality
Simulation
Spawning
Survival
title Biophysical modeling of survival and dispersal of Central and Eastern Baltic Sea flounder (Platichthys flesus) larvae
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