A method to determine the characteristic time‐scales of quasi‐isotropic surface‐layer turbulence over complex terrain: A case‐study in the Adige Valley (Italian Alps)

Falocchi, Marco; Giovannini, Lorenzo; Franceschi, Massimiliano de; Zardi, Dino

doi:10.1002/qj.3444

Cited by 23 publications

(13 citation statements)

References 69 publications

(97 reference statements)

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“…We used wavelets for scale separation, because they are flexible in their application and widely studied. Particularly interesting alternatives are the recursive filters used by Zurbenko and Smith (2017) or Falocchi et al (2018Falocchi et al ( , 2019. We find that, for the FLOSSII database, filtering the velocity on a scale of 1 h is not long enough to obtain a logarithmic profile for a height of 30 m, and a 3-h-averaging scale is required.…”

Section: Discussionmentioning

confidence: 91%

Multiscale Shear Forcing of Turbulence in the Nocturnal Boundary Layer: A Statistical Analysis

Boyko¹,

Vercauteren²

2020

Boundary-Layer Meteorol

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The lower nocturnal boundary layer is governed by intermittent turbulence which is thought to be triggered by sporadic activity of so-called sub-mesoscale motions in a complex way. We analyze intermittent turbulence based on an assumed relation between the vertical gradients of the sub-mean scales and turbulence kinetic energy. We analyze high-resolution nocturnal eddy-correlation data from 30-m tower collected during the Fluxes over Snow Surfaces II field program. The non-turbulent velocity signal is decomposed using a discrete wavelet transform into three ranges of scales interpreted as the mean, jet and sub-mesoscales. The vertical gradients of the sub-mean scales are estimated using finite differences. The turbulence kinetic energy is modelled as a discrete-time autoregressive process with exogenous variables, where the latter ones are the vertical gradients of the sub-mean scales. The parameters of the discrete model evolve in time depending on the locally-dominant turbulence-production scales. The three regimes with averaged model parameters are estimated using a subspace-clustering algorithm which illustrates a weak bimodal distribution in the energy phase space of turbulence and sub-mesoscale motions for the very stable boundary layer. One mode indicates turbulence modulated by sub-mesoscale motions. Furthermore, intermittent turbulence appears if the sub-mesoscale intensity exceeds $$10 \%$$ 10 % of the mean kinetic energy in strong stratification.

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Section: Discussionmentioning

confidence: 91%

Multiscale Shear Forcing of Turbulence in the Nocturnal Boundary Layer: A Statistical Analysis

Boyko¹,

Vercauteren²

2020

Boundary-Layer Meteorol

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“…R αβ 1 and 1 corresponds to small and large submeso effect, respectively. The use of fixed time scales to define the submeso and the small-scale-turbulence contribution (i.e., 30 min and 100 s) is justified only in first approximation: for instance, experiments show that the gap time scale depends on stability [10,30]. Although from the physical point of view length scales are more appealing, time-scales are usually preferred for point measurements, because the time-space transformation is hampered by the inapplicability of Taylor's hypothesis to submeso motions [10].…”

Section: The Submeso Parametermentioning

confidence: 99%

Motions on Second-Order Moment Budgets in the Stable Atmospheric Boundary Layer

Schiavon¹,

Tampieri²,

Caggio³

et al. 2020

Topical Problems of Fluid Mechanics 2020

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The effect of submeso motions on small-scale turbulence is studied considering the budget of the vertical flux of stream-wise momentum, uw , in the atmospheric stable boundary layer (SBL). A parameter expressing the strength of the submeso effect is defined, and the budget is evaluated from observations both for small and large submeso effect. It results that submeso motions affect the efficiency of the vertical transport by small-scale turbulence, having implications on the terms composing the momentum flux budget and on its corresponding closures.

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“…In particular, atmospheric flows over complex terrain are characterized by a continuous and interacting range of scales, from synoptic forcing to mesoscale circulations and turbulence fluctuations. In complex terrain, the mechanical and thermal influence of the orography can modify the large-scale flow and produce smaller-scale motions which would not exist on flat terrain [21][22][23], The relevance of the problem of pollutant dispersion has been a primary driver for many research efforts focused on atmospheric processes over complex terrain in recent decades. In fact, the need for better understanding and suitable modeling of the fate of pollutants in mountainous regions stimulated a number of projects, which involved both experimental activities, such as extensive field campaigns in complex environments, and the advancement of new modeling capabilities over complex terrain, encompassing both meteorological and air quality models.…”

Section: Introductionmentioning

confidence: 99%

Atmospheric Pollutant Dispersion over Complex Terrain: Challenges and Needs for Improving Air Quality Measurements and Modeling

et al. 2020

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Pollutant dispersion processes over complex terrain are much more complicated than over flat areas, as they are affected by atmospheric interactions with the orography at different spatial scales. This paper reviews recent findings and progress in this field, focusing on both experimental and modeling perspectives. It highlights open questions and challenges to our capability for better understanding and representing atmospheric processes controlling the fate of pollutants over mountainous areas. In particular, attention is focused on new measurement techniques for the retrieval of spatially distributed turbulence information and air quality parameters, and on challenges for meteorological and dispersion models to reproduce fine-scale processes influenced by the orography. Finally, specific needs in this field are discussed, along with possible directions for future research efforts.

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A method to determine the characteristic time‐scales of quasi‐isotropic surface‐layer turbulence over complex terrain: A case‐study in the Adige Valley (Italian Alps)

Cited by 23 publications

References 69 publications

Multiscale Shear Forcing of Turbulence in the Nocturnal Boundary Layer: A Statistical Analysis

Multiscale Shear Forcing of Turbulence in the Nocturnal Boundary Layer: A Statistical Analysis

Motions on Second-Order Moment Budgets in the Stable Atmospheric Boundary Layer

Atmospheric Pollutant Dispersion over Complex Terrain: Challenges and Needs for Improving Air Quality Measurements and Modeling

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