The Influence of Submeso Processes on Stable Boundary Layer Similarity Relationships

The Influence of Submeso Processes on Stable Boundary Layer Similarity Relationships

Previous observational studies in the stable boundary layer diverge appreciably on the values of dimensionless ratios between turbulence-related quantities and on their stability dependence. In the present study, the hypothesis that such variability is caused by the influence of locally dependent no...

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Veröffentlicht in:Journal of the atmospheric sciences 2014-01, Vol.71 (1), p.207-225
Hauptverfasser: Acevedo, Otávio C, Costa, Felipe D, Oliveira, Pablo E S, Puhales, Franciano S, Degrazia, Gervásio A, Roberti, Débora R
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Atmospheric boundary layer
Boundary layers
Datasets
Decomposition
Experiments
Fluctuations
Hypotheses
Kinetic energy
Meteorology
Observational studies
Outdoor air quality
Parameters
Ratios
Spectra
Stability
Stable boundary layer
Studies
Temperature fluctuations
Time dependence
Time series
Turbulence
Turbulent fluctuations
Variability
Variables
Velocity
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container_end_page 225
container_issue 1
container_start_page 207
container_title Journal of the atmospheric sciences
container_volume 71
creator Acevedo, Otávio C
Costa, Felipe D
Oliveira, Pablo E S
Puhales, Franciano S
Degrazia, Gervásio A
Roberti, Débora R
description Previous observational studies in the stable boundary layer diverge appreciably on the values of dimensionless ratios between turbulence-related quantities and on their stability dependence. In the present study, the hypothesis that such variability is caused by the influence of locally dependent nonturbulent processes, referred to as submeso, is tested and confirmed. This is done using six datasets collected at sites with different surface coverage. The time-scale dependence of wind components and temperature fluctuations is presented using the multiresolution decomposition, which allows the identification of the turbulence and submeso contributions to spectra and cospectra. In the submeso range, the spectra of turbulence kinetic energy range increases exponentially with time scale. The exponent decreases with the magnitude of the turbulent fluctuations at a similar manner at all sites. This fact is used to determine the smaller time scale with relevant influence of submeso processes and a ratio that quantifies the relative importance of such nonturbulent processes with respect to turbulence. Based on that, values for the local stability parameter that are unaffected by nonturbulent processes are found. It is shown that the dimensionless ratios do not usually converge to a given value as the time scale increases and that it is as a consequence of the locally dependent submeso influence. The ratios and their stability dependence are determined at the time scales with least influence of nonturbulent processes, but significant site-to-site variability persists. Combining all datasets, expressions for the dependence of the dimensionless ratios on the local stability parameter that minimize the role of the submeso contribution are proposed.
doi_str_mv 10.1175/JAS-D-13-0131.1
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source American Meteorological Society; EZB-FREE-00999 freely available EZB journals; Alma/SFX Local Collection
subjects Atmospheric boundary layer
Boundary layers
Datasets
Decomposition
Experiments
Fluctuations
Hypotheses
Kinetic energy
Meteorology
Observational studies
Outdoor air quality
Parameters
Ratios
Spectra
Stability
Stable boundary layer
Studies
Temperature fluctuations
Time dependence
Time series
Turbulence
Turbulent fluctuations
Variability
Variables
Velocity
title The Influence of Submeso Processes on Stable Boundary Layer Similarity Relationships
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