Dependence of near‐surface similarity scaling on the anisotropy of atmospheric turbulence

Stiperski, Ivana; Calaf, Marc

doi:10.1002/qj.3224

Cited by 73 publications

(112 citation statements)

References 71 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…This scatter also persists despite the advanced postprocessing techniques and progressively more restrictive quality criteria imposed on the data. In an effort to overcome these challenges, Stiperski and Calaf () employed a novel approach by examining traditional similarity scaling relations over flat and horizontally homogeneous terrain based on clustering the data according to anisotropy. Results of this work illustrated a strong dependence between the quality of the scaling fit and the characteristic topology of the turbulent flow, showing that the similarity scaling significantly improves when the turbulent flow is a priori classified according to the anisotropy type.…”

Section: Introductionmentioning

confidence: 77%

“…The data set that conforms to the flat and horizontally homogeneous terrain the best is CASES‐99. Already studied in Stiperski and Calaf (), it forms the basis of the current analysis. The data consist of a month of measurements from a 60‐m tower with 7 levels of sonic anemometers.…”

Section: Methodsmentioning

confidence: 99%

“…On the other hand, one‐component turbulence strongly departs from common scaling curves. These results, together with the possibility of predicting the anisotropy type based on larger‐scale variables as shown in Stiperski and Calaf (), promised to be a powerful tool to improve similarity scaling relations.…”

Section: Introductionmentioning

confidence: 99%

“…In this work, and based on the earlier approach first introduced in Stiperski and Calaf (), we present a new interpretation of the a priori mismatch of near‐surface data in complex terrain and traditional scaling relations based on the anisotropy of the turbulence stress tensor. The results show that similar to flat and horizontally homogeneous terrain, separating the complex terrain data according to anisotropy significantly improves scaling, offering a pathway toward a unified theory of turbulence.…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Scaling, Anisotropy, and Complexity in Near‐Surface Atmospheric Turbulence

2019

Self Cite

View full text Add to dashboard Cite

The development of a unified similarity scaling has so far failed over complex surfaces, as scaling studies show large deviations from the empirical formulations developed over flat and horizontally homogeneous terrain as well as large deviations between the different complex terrain data sets. However, a recent study of turbulence anisotropy for flat and horizontally homogeneous terrain has shown that separating the data according to the limiting states of anisotropy (isotropic, two‐component axisymmetric and one‐component turbulence) improves near‐surface scaling. In this paper we explore whether this finding can be extended to turbulence over inclined and horizontally heterogeneous surfaces by examining near‐surface scaling for 12 different data sets obtained over terrain ranging from flat to mountainous. Although these data sets show large deviations in scaling when all anisotropy types are examined together, the separation according to the limiting states of anisotropy significantly improves the collapse of data onto common scaling relations, indicating the possibility of a unified framework for turbulence scaling. A measure of turbulence complexity is developed, and the causes for the breakdown of scaling and the physical mechanisms behind the turbulence complexity encountered over complex terrain are identified and shown to be related to the distance to the isotropic state, prevalence of directional shear with height in mountainous terrain, and the deviations from isotropy in the inertial subrange.

show abstract

Section: Introductionmentioning

confidence: 77%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Scaling, Anisotropy, and Complexity in Near‐Surface Atmospheric Turbulence

2019

Self Cite

View full text Add to dashboard Cite

show abstract

“…While methods to deal with non-stationarity have been in use for some time now [77], turbulence anisotropy over mountainous terrain is a scarcely explored issue that deserves further investigation [78,79]. A new metric to characterize turbulence anisotropy [80] has recently been used to demonstrate that different states of anisotropy correspond to different similarity relations, especially for horizontal variances, and to confirm that separating the experimental data according to anisotropy significantly improves the match to MOST scaling laws. Since anisotropy in complex terrain may be related to terrain features [81], systematic anisotropy analysis could help identify turbulence properties that hold generally for any complex terrain site and that can be used to generalize scaling laws.…”

Section: Fundamental Properties Of Turbulence Over Complex Terrainmentioning

confidence: 99%

Exchange Processes in the Atmospheric Boundary Layer Over Mountainous Terrain

et al. 2018

Self Cite

View full text Add to dashboard Cite

Abstract:The exchange of heat, momentum, and mass in the atmosphere over mountainous terrain is controlled by synoptic-scale dynamics, thermally driven mesoscale circulations, and turbulence. This article reviews the key challenges relevant to the understanding of exchange processes in the mountain boundary layer and outlines possible research priorities for the future. The review describes the limitations of the experimental study of turbulent exchange over complex terrain, the impact of slope and valley breezes on the structure of the convective boundary layer, and the role of intermittent mixing and wave-turbulence interaction in the stable boundary layer. The interplay between exchange processes at different spatial scales is discussed in depth, emphasizing the role of elevated and ground-based stable layers in controlling multi-scale interactions in the atmosphere over and near mountains. Implications of the current understanding of exchange processes over mountains towards the improvement of numerical weather prediction and climate models are discussed, considering in particular the representation of surface boundary conditions, the parameterization of sub-grid-scale exchange, and the development of stochastic perturbation schemes.

show abstract

Dependence of near‐surface similarity scaling on the anisotropy of atmospheric turbulence

Stiperski

Calaf

2018

Quart J Royal Meteoro Soc

View full text Add to dashboard Cite

Turbulence data from the CASES‐99 field experiment, over comparatively horizontally homogeneous and flat terrain, are separated based on the anisotropy of the Reynolds stress tensor (into isotropic, two‐component axisymmetric and one‐component turbulence) and flux‐variance similarity scaling relations are tested. Results illustrate that different states of anisotropy correspond to different similarity relations, especially under unstable stratification. Experimental data with close to isotropic turbulence match similarity relationships well. On the other hand, very anisotropic turbulence deviates significantly from the traditional scaling relations. We examine in detail the characteristics of these states of anisotropy, identify conditions in which they occur and connect them with different governing parameters. The governing parameters of turbulence anisotropy are shown to be different for stable and unstable stratification, but are able to delineate clearly the conditions in which each of the anisotropy states occurs.

show abstract

Dependence of near‐surface similarity scaling on the anisotropy of atmospheric turbulence

Cited by 73 publications

References 71 publications

Scaling, Anisotropy, and Complexity in Near‐Surface Atmospheric Turbulence

Scaling, Anisotropy, and Complexity in Near‐Surface Atmospheric Turbulence

Exchange Processes in the Atmospheric Boundary Layer Over Mountainous Terrain

Dependence of near‐surface similarity scaling on the anisotropy of atmospheric turbulence

Contact Info

Product

Resources

About