Dispersal kernel estimation: A comparison of empirical and modelled particle dispersion in a coastal marine system

Early life-stage dispersal influences recruitment and is of significance in explaining the distribution and connectivity of marine species. Motivations for quantifying dispersal range from biodiversity conservation to the design of marine reserves and the mitigation of species invasions. Here we com...

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Published inEstuarine, coastal and shelf science Vol. 133; pp. 11 - 22
Main Authors Hrycik, Janelle M., Chassé, Joël, Ruddick, Barry R., Taggart, Christopher T.
Format Journal Article
LanguageEnglish
Published Kidlington Elsevier Ltd 20.11.2013
Elsevier
Subjects
advection and diffusion
Animal and plant ecology
Animal, plant and microbial ecology
Biological and medical sciences
Brackish water ecosystems
connectivity
dispersal kernel
empirical-model comparisons
Fundamental and applied biological sciences. Psychology
Lagrangian particle tracing
marine
Sea water ecosystems
Synecology
empirical-model comparisons
advection and diffusion
connectivity
Kp
dispersal kernel
VP
Lagrangian particle tracing
MAP
marine
Brackish water environment
Empirical model
Dispersion
Marine environment
Particle
Advection
Diffusion
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Summary:Early life-stage dispersal influences recruitment and is of significance in explaining the distribution and connectivity of marine species. Motivations for quantifying dispersal range from biodiversity conservation to the design of marine reserves and the mitigation of species invasions. Here we compare estimates of real particle dispersion in a coastal marine environment with similar estimates provided by hydrodynamic modelling. We do so by using a system of magnetically attractive particles (MAPs) and a magnetic-collector array that provides measures of Lagrangian dispersion based on the time-integration of MAPs dispersing through the array. MAPs released as a point source in a coastal marine location dispersed through the collector array over a 5–7 d period. A virtual release and observed (real-time) environmental conditions were used in a high-resolution three-dimensional hydrodynamic model to estimate the dispersal of virtual particles (VPs). The number of MAPs captured throughout the collector array and the number of VPs that passed through each corresponding model location were enumerated and compared. Although VP dispersal reflected several aspects of the observed MAP dispersal, the comparisons demonstrated model sensitivity to the small-scale (random-walk) particle diffusivity parameter (Kp). The one-dimensional dispersal kernel for the MAPs had an e-folding scale estimate in the range of 5.19–11.44 km, while those from the model simulations were comparable at 1.89–6.52 km, and also demonstrated sensitivity to Kp. Variations among comparisons are related to the value of Kp used in modelling and are postulated to be related to MAP losses from the water column and (or) shear dispersion acting on the MAPs; a process that is constrained in the model. Our demonstration indicates a promising new way of 1) quantitatively and empirically estimating the dispersal kernel in aquatic systems, and 2) quantitatively assessing and (or) improving regional hydrodynamic models.
ISSN:0272-7714
1096-0015
DOI:10.1016/j.ecss.2013.06.023