Stochastic models for phytoplankton dynamics in Mediterranean Sea

•Use of stochastic advection–reaction–diffusion models for picophytoplankton dynamics.•Spatio-temporal dynamics of phytoplankton concentration in real marine ecosystems.•Good agreement of equilibrium profiles of chlorophyll a concentration with real data.•Depth and magnitude of the Deep Chlorophyll...

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Bibliographic Details
Published in:Ecological complexity 2016-09, Vol.27, p.84-103
Main Authors: Valenti, D., Denaro, G., Spagnolo, B., Mazzola, S., Basilone, G., Conversano, F., Brunet, C., Bonanno, A.
Format: Article
Language:English
Subjects:
Deep chlorophyll maximum
Marine ecosystems
Phytoplankton dynamics
Prochlorococcus
Random processes
Spatial ecology
Stochastic differential equations
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Summary:•Use of stochastic advection–reaction–diffusion models for picophytoplankton dynamics.•Spatio-temporal dynamics of phytoplankton concentration in real marine ecosystems.•Good agreement of equilibrium profiles of chlorophyll a concentration with real data.•Depth and magnitude of the Deep Chlorophyll Maxima fitting very well real findings.•Analysis contributing to devise predictive models for picophytoplankton dynamics. In this paper, we review some results obtained from three one-dimensional stochastic models, which were used to analyze picophytoplankton dynamics in two sites of the Mediterranean Sea. Firstly, we present a stochastic advection–reaction–diffusion model to describe the vertical spatial distribution of picoeukaryotes in a site of the Sicily Channel. The second model, which is an extended version of the first one, is used to obtain the vertical stationary profiles of two groups of picophytoplankton, i.e. Pelagophytes and Prochlorococcus, in the same marine site as in the previous case. Here, we include intraspecific competition of picophytoplanktonic groups for limiting factors, i.e. light intensity and nutrient concentration. Finally, we analyze the spatio-temporal behaviour of five picophytoplankton populations in a site of the Tyrrhenian Sea by using a reaction–diffusion–taxis model. The study is performed, taking into account the seasonal changes of environmental variables, obtained starting from experimental findings. The multiplicative noise source, present in all three models, mimics the random fluctuations of temperature and velocity field. The vertical profiles of chlorophyll concentration obtained from the stochastic models show a good agreement with experimental data sampled in the two marine sites considered. The results could be useful to devise a new class of models based on a stochastic approach and able to predict future changes in biomass primary production.
ISSN:1476-945X
DOI:10.1016/j.ecocom.2015.06.001