Second‐moment budgets in cloud topped boundary layers: A large‐eddy simulation study

Heinze, Rieke; Mironov, Dmitrii; Raasch, Siegfried

doi:10.1002/2014ms000376

Cited by 49 publications

(50 citation statements)

References 55 publications

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“…Cloudy boundary layers have been simulated using bulk cloud microphysics for cold-air outbreaks by Gryschka et al (2008) as well as for the analysis of second-order budgets in cloudtopped boundary layers for BOMEX and DYCOMS-II 10 (see Stevens et al, 2005) experiments by Heinze et al (2015). Recently, the embedded LCM has been employed for studying the effect of turbulence on the droplet dynamics and growth (Lee et al, 2014;Riechelmann et al, 2015), and for investigating the entrainment (of aerosols) at the edges of cumulus clouds (Hoffmann et al, 2015(Hoffmann et al, , 2014.…”

Section: Past and Current Research Fieldsmentioning

confidence: 99%

“…Over the last 15 years, PALM has been applied for the simulation of a variety of boundary layers, ranging from heterogeneously heated convective boundary layers (e.g., Raasch and Harbusch, 2001;Letzel and Raasch, 2003;Maronga and Raasch, 2013), urban canopy flows (e.g., Park et al, 2012;Kanda et al, 2013), and cloudy boundary layers (e.g., Riechelmann et al, 2012;Hoffmann et al, 2015;Heinze et al, 2015). Moreover, it has been used for studies of the oceanic mixed layer (OML, e.g., Noh et al, 2010Noh et al, , 2011 and recently for studying the feedback between atmosphere and ocean by Esau (2014).…”

Section: Introductionmentioning

confidence: 99%

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The Parallelized Large-Eddy Simulation Model (PALM) version 4.0 for atmospheric and oceanic flows: model formulation, recent developments, and future perspectives

et al. 2015

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Abstract. In this paper we present the current version of the Parallelized Large-Eddy Simulation Model (PALM) whose core has been developed at the Institute of Meteorology and Climatology at Leibniz Universität Hannover (Germany). PALM is a Fortran 95-based code with some Fortran 2003 extensions and has been applied for the simulation of a variety of atmospheric and oceanic boundary layers for more than 15 years. PALM is optimized for use on massively parallel computer architectures and was recently ported to general-purpose graphics processing units. In the present paper we give a detailed description of the current version of the model and its features, such as an embedded Lagrangian cloud model and the possibility to use Cartesian topography. Moreover, we discuss recent model developments and future perspectives for LES applications.

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Section: Past and Current Research Fieldsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The Parallelized Large-Eddy Simulation Model (PALM) version 4.0 for atmospheric and oceanic flows: model formulation, recent developments, and future perspectives

et al. 2015

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“…Typically, higher-order moments from LES are deduced from a spatial (horizontal) average (e.g., Heinze et al, 2015) as opposed to lidar measurements, which define turbulence as departure from a temporal mean. To account for this difference, variances from LES are shown in two different ways in Fig.…”

Section: Vertical Structurementioning

confidence: 99%

Evaluation of large-eddy simulations forced with mesoscale model output for a multi-week period during a measurement campaign

et al. 2017

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Abstract. Large-eddy simulations (LESs) of a multi-week period during the HD(CP) 2 (High-Definition Clouds and Precipitation for advancing Climate Prediction) Observational Prototype Experiment (HOPE) conducted in Germany are evaluated with respect to mean boundary layer quantities and turbulence statistics. Two LES models are used in a semi-idealized setup through forcing with mesoscale model output to account for the synoptic-scale conditions. Evaluation is performed based on the HOPE observations. The mean boundary layer characteristics like the boundary layer depth are in a principal agreement with observations. Simulating shallow-cumulus layers in agreement with the measurements poses a challenge for both LES models. Variance profiles agree satisfactorily with lidar measurements. The results depend on how the forcing data stemming from mesoscale model output are constructed. The mean boundary layer characteristics become less sensitive if the averaging domain for the forcing is large enough to filter out mesoscale fluctuations.

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“…[], and Heinze et al . []. In the Reynolds‐stress budget, for example, the pressure terms act to redistribute the kinetic energy produced by shear and/or buoyancy between the velocity‐variance components, thus reducing the turbulence anisotropy generated by shear, buoyancy, and rotation.…”

Section: Introductionmentioning

confidence: 99%

“…Heinze et al . [, hereinafter H15] analyzed the second‐moment budgets in cloud‐topped boundary‐layer flows generated with LES and demonstrated that the pressure‐scrambling terms are of paramount importance in maintaining the Reynolds‐stress and the scalar‐flux budgets. A step forward is made in the present paper, where a detailed analysis of the pressure‐scrambling terms is performed.…”

Section: Introductionmentioning

confidence: 99%

Analysis of pressure‐strain and pressure gradient‐scalar covariances in cloud‐topped boundary layers: A large‐eddy simulation study

Heinze

Mironov

Raasch

2016

J Adv Model Earth Syst

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A detailed analysis of the pressure-scrambling terms (i.e., the pressure-strain and pressure gradient-scalar covariances) in the Reynolds-stress and scalar-flux budgets for cloud-topped boundary layers (CTBLs) is performed using high-resolution large-eddy simulation (LES). Two CTBLs are simulatedone with trade wind shallow cumuli, and the other with nocturnal marine stratocumuli. The pressurescrambling terms are decomposed into contributions due to turbulence-turbulence interactions, mean velocity shear, buoyancy, and Coriolis effects. Commonly used models of these contributions, including a simple linear model most often used in geophysical applications and a more sophisticated two-componentlimit (TCL) nonlinear model, are tested against the LES data. The decomposition of the pressure-scrambling terms shows that the turbulence-turbulence and buoyancy contributions are most significant for cloudtopped boundary layers. The Coriolis contribution is negligible. The shear contribution is generally of minor importance inside the cloudy layers, but it is the leading-order contribution near the surface. A comparison of models of the pressure-scrambling terms with the LES data suggests that the more complex TCL model is superior to the simple linear model only for a few contributions. The linear model is able to reproduce the principal features of the pressure-scrambling terms reasonably well. It can be applied in the second-order turbulence modeling of cloud-topped boundary layer flows, provided some uncertainties are tolerated.

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Second‐moment budgets in cloud topped boundary layers: A large‐eddy simulation study

Cited by 49 publications

References 55 publications

The Parallelized Large-Eddy Simulation Model (PALM) version 4.0 for atmospheric and oceanic flows: model formulation, recent developments, and future perspectives

The Parallelized Large-Eddy Simulation Model (PALM) version 4.0 for atmospheric and oceanic flows: model formulation, recent developments, and future perspectives

Evaluation of large-eddy simulations forced with mesoscale model output for a multi-week period during a measurement campaign

Analysis of pressure‐strain and pressure gradient‐scalar covariances in cloud‐topped boundary layers: A large‐eddy simulation study

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