Vertical swimming behavior influences the dispersal of simulated oyster larvae in a coupled particle-tracking and hydrodynamic model of Chesapeake Bay

Because planktonic organisms have swimming speeds that are orders of magnitude lower than horizontal current velocities, it is unclear whether behavior of weak-swimming bivalve larvae could influence dispersal distance, encounters with suitable habitat, or subpopulation connectivity. We used a numer...

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Veröffentlicht in:Marine ecology. Progress series (Halstenbek) 2008-05, Vol.359, p.99-115
Hauptverfasser: North, E. W., Schlag, Z., Hood, R. R., Li, M., Zhong, L., Gross, T., Kennedy, V. S.
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Sprache:eng
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Zusammenfassung:Because planktonic organisms have swimming speeds that are orders of magnitude lower than horizontal current velocities, it is unclear whether behavior of weak-swimming bivalve larvae could influence dispersal distance, encounters with suitable habitat, or subpopulation connectivity. We used a numerical approach to investigate whether these processes could be affected by species-specific differences in larval vertical swimming behavior of 2 oyster species (Crassostrea virginicaandC. ariakensis) in Chesapeake Bay, a partially mixed estuary. A coupled particle-tracking and hydrodynamic model was forced with observed winds and freshwater flow and included the best available estimate of present-day oyster habitat. Model scenarios were conducted with hydrodynamic predictions from June to September, 1995 to 1999, to simulate a range of environmental conditions. Simple larval swimming behaviors were parameterized for the 2 oyster species with results from preliminary laboratory experiments and literature. To isolate the effect of circulation, settlement habitat, and larval behavior on the spatial trajectories of particles, vertical swimming velocity was the only biological process represented in the model; egg production and larval growth were not included. Differences in larval swimming behavior had significant consequences for particle transport in Chesapeake Bay by influencing dispersal distances, transport success, and the degree of connectivity between ‘subpopulations’ in different tributaries. Most particles (>96%) did not return to the same reef on which they were released, and there were behavior-dependent differences in spatial patterns of the ‘source’ and ‘sink’ characteristics of oyster reefs. Simulated larval behavior had greater influence on spatial patterns of transport success than did interannual differences in circulation patterns. These model results have implications for fisheries management and oyster restoration activities.
ISSN:0171-8630
1616-1599
DOI:10.3354/meps07317