Analysis of Different Gray Zone Treatments in WRF-LES Real Case Simulations

Doubrawa, Paula; Montornès, Alex; Barthelmie, R.J.; Pryor, Sara C.; Casso, Pau

doi:10.5194/wes-2017-61

Cited by 4 publications

(4 citation statements)

References 18 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The Advanced Research WRF (WRF-ARW) is a state-of-the-art open source mesoscale atmospheric model, developed by National Center for Atmospheric Research (NCAR) for both research and numerical weather prediction purposes (Powers et al, 2017). This model, which is probably the most popular meteorological (it also has a climatic version) model worldwide, has the capability to be used for a wide range of applications, such as real-time numerical weather prediction, data assimilation, parameterized-physics research, regional climate simulations, air quality modeling, atmosphere-ocean coupling, and idealized simulations (Blossey et al, 2013;Doubrawa et al, 2018;Jimenez et al, 2016;Lin et al, 2015;Moeng et al, 2007;Montornès et al, 2016;Wang et al, 2009;Yamaguchi & Feingold, 2012;Zhong et al, 2016). In addition, it can be ran at different domains and offers various options for parameterization of convective processes, turbulent transports, evolution of surface temperature and soil moisture, and soil-air interactions (Ruiz-Arias et al, 2013;Skamarock et al, 2008).…”

Section: Model Descriptionmentioning

confidence: 99%

Transition Zone Radiative Effects in Shortwave Radiation Parameterizations: Case of Weather Research and Forecasting Model

2019

View full text Add to dashboard Cite

A number of studies have stated that the shift from a cloud‐free to cloudy atmosphere (and vice versa) contains an additional phase, named “Transition (or twilight) Zone”. However, the information available about radiative effects of this phase is very limited. Consequently, in most meteorological and climate studies, the area corresponding to the transition zone is considered as an area containing aerosol or optically thin clouds. This study investigates the differences in shortwave radiative effects driven from different treatments of the transition zone. To this aim, three of the shortwave radiation parameterizations (NewGoddard, Rapid Radiative Transfer Model for Global circulation models, and Fu‐Liou‐Gu) included in the Advanced Research Weather Research and Forecasting Model (WRF‐ARW) were isolated and adapted for one‐dimensional vertical simulations. These parameterizations were then utilized to perform simulations under ideal “cloud” and “aerosol” modes, for different values of (i) cloud optical depths resulting from different sizes of ice crystals or liquid droplets and mixing ratios; and (ii) different aerosol optical depths combined with various aerosol types. The resulting shortwave broadband total, direct, and diffuse irradiances at the Earth surface were analyzed. The uncertainties originated from different assumptions of a situation regarding to the transition zone are quite substantial for all the parameterizations. For all the parameterizations, direct and total irradiances are the least and most sensitive irradiances to different treatments of the transition zone, respectively. Differences in the radiative effects of transition zone dominantly result from the difference between the radiative effects of clouds and aerosols (different types), not from cloud type or droplet/crystal size.

show abstract

Section: Model Descriptionmentioning

confidence: 99%

Transition Zone Radiative Effects in Shortwave Radiation Parameterizations: Case of Weather Research and Forecasting Model

2019

View full text Add to dashboard Cite

show abstract

“…They found that vertical motions and convective rolls are intensified in the subkilometer simulations with the scale-aware PBL parameterization. Since then, several studies have further investigated the effects of the SH parameterization and found that it performs better at gray-zone resolutions than its conventional parameterization of Hong et al (2006), which scheme has been developed at Yonsei University and thus is named YSU hereinafter (e.g., Doubrawa et al 2018;Xu et al 2018). However, all of these studies consider dry CBLs; the scale-aware PBL parameterization has not been tested for moist CBLs, where PBL parameterizations interact strongly with microphysical processes within convection.…”

Section: Introductionmentioning

confidence: 99%

Effect of Scale-Aware Nonlocal Planetary Boundary Layer Scheme on Lake-Effect Precipitation at Gray-Zone Resolutions

Choi

Han

2020

Monthly Weather Review

View full text Add to dashboard Cite

The effects of a nonlocal planetary boundary layer (PBL) scheme that considers scale dependency in the parameterized turbulent vertical transport are investigated for a case of wintertime lake-effect precipitation over Korea at gray-zone resolutions using a mesoscale model. An experiment using the scale-aware PBL scheme is compared with that using a conventional PBL scheme, which shows that the simulated precipitation amount at a resolution of less than 1 km is smaller with the scale-aware PBL scheme. The role of turbulent processes in simulating lake-effect precipitation is understood through interaction with microphysical processes. When the scale-aware PBL scheme is used, liquid water content is increased while ice water content is reduced. The higher cloud water content is because of enhanced condensation with stronger updrafts, attributed to the suppression of parameterized turbulent mixing. This results in higher rainwater content by enhancing autoconversion and accretion from cloud water to rainwater. The cloud ice content is reduced mainly because of the suppressed deposition and enhanced sublimation centered near the PBL top, and the snow content is reduced mainly because of the enhanced sublimation below and near the PBL top and suppressed growth of cloud ice to snow. The lower ice water content is mainly due to the drier PBL, attributed to the enhanced resolved (suppressed parameterized) turbulent moisture transport and enhanced condensation. The melting of a smaller amount of snow under dominant cold rain processes is responsible for the reduced surface precipitation with the scale-aware PBL scheme.

show abstract

“…The further 1 h outputs with 5 s interval (approximately the advection timescale of the smallest resolved eddies, which is equivalently twice the grid resolution of 20 m) were used for the analysis. We take advantage of the homogeneous turbulence in the spanwise direction (Ghannam et al, 2015) and calculate all resolved-scale turbulent quantities by averaging in the spanwise direction (the y direction) and in time t over the last 1 h period. This averaging is referred to as "the y − t averaging" hereafter and is denoted by ϕ , for example, for the y − t-averaged ϕ.…”

Section: Model Coupling and Configurationmentioning

confidence: 99%

Implementation of a synthetic inflow turbulence generator in idealised WRF v3.6.1 large eddy simulations under neutral atmospheric conditions

2021

View full text Add to dashboard Cite

Abstract. A synthetic inflow turbulence generator was implemented in the idealised Weather Research and Forecasting large eddy simulation (WRF-LES v3.6.1) model under neutral atmospheric conditions. This method is based on an exponential correlation function and generates a series of two-dimensional slices of data which are correlated both in space and in time. These data satisfy a spectrum with a near “-5/3” inertial subrange, suggesting its excellent capability for high Reynolds number atmospheric flows. It is more computationally efficient than other synthetic turbulence generation approaches, such as three-dimensional digital filter methods. A WRF-LES simulation with periodic boundary conditions was conducted to provide prior mean profiles of first and second moments of turbulence for the synthetic turbulence generation method, and the results of the periodic case were also used to evaluate the inflow case. The inflow case generated similar turbulence structures to those of the periodic case after a short adjustment distance. The inflow case yielded a mean velocity profile and second-moment profiles that agreed well with those generated using periodic boundary conditions, after a short adjustment distance. For the range of the integral length scales of the inflow turbulence (±40 %), its effect on the mean velocity profiles is negligible, whereas its influence on the second-moment profiles is more visible, in particular for the smallest integral length scales, e.g. those with the friction velocity of less than 4 % error of the reference data at x/H=7. This implementation enables a WRF-LES simulation of a horizontally inhomogeneous case with non-repeated surface land-use patterns and can be extended so as to conduct a multi-scale seamless nesting simulation from a meso-scale domain with a kilometre-scale resolution down to LES domains with metre-scale resolutions.

show abstract

Analysis of Different Gray Zone Treatments in WRF-LES Real Case Simulations

Cited by 4 publications

References 18 publications

Transition Zone Radiative Effects in Shortwave Radiation Parameterizations: Case of Weather Research and Forecasting Model

Transition Zone Radiative Effects in Shortwave Radiation Parameterizations: Case of Weather Research and Forecasting Model

Effect of Scale-Aware Nonlocal Planetary Boundary Layer Scheme on Lake-Effect Precipitation at Gray-Zone Resolutions

Implementation of a synthetic inflow turbulence generator in idealised WRF v3.6.1 large eddy simulations under neutral atmospheric conditions

Contact Info

Product

Resources

About