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Scale-Dependent Turbulent Dynamics and Phase-Space Behavior of the Stable Atmospheric Boundary Layer

Francesco Carbone, Tommaso Alberti, L. Sorriso‐Valvo, Daniele Telloni, Francesca Sprovieri, Nicola Pirrone

2020Atmosphere10 citationsDOIOpen Access PDF

Abstract

The structure of turbulent dynamics in a stable atmospheric boundary layer was studied by means of a phase-space description. Data from the CASES-99 experiment, decomposed in local modes (with increasing time scale) using empirical mode decomposition, were analyzed in order to extract the proper time lag and the embedding dimension of the phase-space manifold, and subsequently to estimate their scale-dependent correlation dimension. Results show that the dynamics are low-dimensional and anisotropic for a large scale, where the flow is dominated by the bulk motion. Then, they become progressively more high-dimensional while transiting into the inertial sub-range. Finally, they reach three-dimensionality in the range of scales compatible with the center of the inertial sub-range, where the phase-space-filling turbulent fluctuations dominate the dynamics.

Topics & Concepts

TurbulencePhysicsCurse of dimensionalityBoundary layerScale (ratio)Phase spaceInertial frame of referencePlanetary boundary layerStatistical physicsMechanicsClassical mechanicsMathematicsThermodynamicsQuantum mechanicsStatisticsWind and Air Flow StudiesFluid Dynamics and Turbulent FlowsMeteorological Phenomena and Simulations