Microscale Complexity in the Ocean: Turbulence, Intermittency and Plankton Life

L. Seuront

Mathematical Modelling of Natural Phenomena (2008)

  • Volume: 3, Issue: 3, page 1-41
  • ISSN: 0973-5348

Abstract

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This contribution reviews the nonlinear stochastic properties of turbulent velocity and passive scalar intermittent fluctuations in Eulerian and Lagrangian turbulence. These properties are illustrated with original data sets of (i) velocity fluctuations collected in the field and in the laboratory, and (ii) temperature, salinity and in vivo fluorescence (a proxy of phytoplankton biomass, i.e. unicelled vegetals passively advected by turbulence) sampled from highly turbulent coastal waters. The strength of three of the most popular models describing intermittent fluctuations (the lognormal, log-Lévy and log-Poisson models) to fit the distribution of in vivo fluorescence has subsequently been critically assessed. A theoretical formulation for the stochastic properties of biologically active scalars is also provided and validated. Finally, the potential effect of the intermittent properties of turbulent velocity fluctuations on processes relevant to the life of plankton organisms are theoretically investigated. It is shown that the intermittent nature of microscale turbulence may result in (i) a decrease in the rate of nutrient fluxes towards non-motile phytoplankton cells (6-62 %), (ii) a decrease in the physical coagulation of phytoplankton cells (25-48 %) and in the subsequent phytoplankton aggregate volumes (22-41 %), and (iii) a decrease of the turbulence contribution to predator-prey encounter rates (25-50 %).

How to cite

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Seuront, L.. "Microscale Complexity in the Ocean: Turbulence, Intermittency and Plankton Life." Mathematical Modelling of Natural Phenomena 3.3 (2008): 1-41. <http://eudml.org/doc/222383>.

@article{Seuront2008,
abstract = {This contribution reviews the nonlinear stochastic properties of turbulent velocity and passive scalar intermittent fluctuations in Eulerian and Lagrangian turbulence. These properties are illustrated with original data sets of (i) velocity fluctuations collected in the field and in the laboratory, and (ii) temperature, salinity and in vivo fluorescence (a proxy of phytoplankton biomass, i.e. unicelled vegetals passively advected by turbulence) sampled from highly turbulent coastal waters. The strength of three of the most popular models describing intermittent fluctuations (the lognormal, log-Lévy and log-Poisson models) to fit the distribution of in vivo fluorescence has subsequently been critically assessed. A theoretical formulation for the stochastic properties of biologically active scalars is also provided and validated. Finally, the potential effect of the intermittent properties of turbulent velocity fluctuations on processes relevant to the life of plankton organisms are theoretically investigated. It is shown that the intermittent nature of microscale turbulence may result in (i) a decrease in the rate of nutrient fluxes towards non-motile phytoplankton cells (6-62 %), (ii) a decrease in the physical coagulation of phytoplankton cells (25-48 %) and in the subsequent phytoplankton aggregate volumes (22-41 %), and (iii) a decrease of the turbulence contribution to predator-prey encounter rates (25-50 %). },
author = {Seuront, L.},
journal = {Mathematical Modelling of Natural Phenomena},
keywords = {patchiness; intermittency; plankton; Eulerian and Lagrangian turbulence; Eulerian and Lagrangian turbulence},
language = {eng},
month = {11},
number = {3},
pages = {1-41},
publisher = {EDP Sciences},
title = {Microscale Complexity in the Ocean: Turbulence, Intermittency and Plankton Life},
url = {http://eudml.org/doc/222383},
volume = {3},
year = {2008},
}

TY - JOUR
AU - Seuront, L.
TI - Microscale Complexity in the Ocean: Turbulence, Intermittency and Plankton Life
JO - Mathematical Modelling of Natural Phenomena
DA - 2008/11//
PB - EDP Sciences
VL - 3
IS - 3
SP - 1
EP - 41
AB - This contribution reviews the nonlinear stochastic properties of turbulent velocity and passive scalar intermittent fluctuations in Eulerian and Lagrangian turbulence. These properties are illustrated with original data sets of (i) velocity fluctuations collected in the field and in the laboratory, and (ii) temperature, salinity and in vivo fluorescence (a proxy of phytoplankton biomass, i.e. unicelled vegetals passively advected by turbulence) sampled from highly turbulent coastal waters. The strength of three of the most popular models describing intermittent fluctuations (the lognormal, log-Lévy and log-Poisson models) to fit the distribution of in vivo fluorescence has subsequently been critically assessed. A theoretical formulation for the stochastic properties of biologically active scalars is also provided and validated. Finally, the potential effect of the intermittent properties of turbulent velocity fluctuations on processes relevant to the life of plankton organisms are theoretically investigated. It is shown that the intermittent nature of microscale turbulence may result in (i) a decrease in the rate of nutrient fluxes towards non-motile phytoplankton cells (6-62 %), (ii) a decrease in the physical coagulation of phytoplankton cells (25-48 %) and in the subsequent phytoplankton aggregate volumes (22-41 %), and (iii) a decrease of the turbulence contribution to predator-prey encounter rates (25-50 %).
LA - eng
KW - patchiness; intermittency; plankton; Eulerian and Lagrangian turbulence; Eulerian and Lagrangian turbulence
UR - http://eudml.org/doc/222383
ER -

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