Large-Eddy Simulations of a Drizzling, Stratocumulus-Topped Marine Boundary Layer

Ackerman, Andrew S.; vanZanten, Margreet C.; Stevens, Björn; Savic-Jovcic, Verica; Bretherton, Christopher S.; Chlond, Andreas; Golaz, Jean‐Christophe; Jiang, Hongli; Khairoutdinov, Marat; Krueger, Steven K.; Lewellen, D. C.; Lock, A. P.; Moeng, Chin‐Hoh; Nakamura, Kozo; Petters, M. D.; Snider, Jefferson R.; Weinbrecht, Sonja; Zulauf, Michael A.

doi:10.1175/2008mwr2582.1

Cited by 221 publications

(403 citation statements)

References 71 publications

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“…The horizontal grid spacing of these LES cases is fixed at 50 m, while the vertical grid is stretched, with a minimum spacing of 5 m near the surface and the capping temperature inversion to better resolve small-scale turbulence there. Further details of the model setup for the DYCOMS-II case are provided in Ackerman et al (2009). The ATEX cases are updated model runs with increased spatial resolution that are similar to the cases discussed in Fridlind and Ackerman (2011).…”

Section: Model and Methodologymentioning

confidence: 99%

Comparisons of bispectral and polarimetric retrievals of marine boundary layer cloud microphysics: case studies using a LES–satellite retrieval simulator

et al. 2018

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Abstract. Many passive remote-sensing techniques have been developed to retrieve cloud microphysical properties from satellite-based sensors, with the most common approaches being the bispectral and polarimetric techniques. These two vastly different retrieval techniques have been implemented for a variety of polar-orbiting and geostationary satellite platforms, providing global climatological data sets. Prior instrument comparison studies have shown that there are systematic differences between the droplet size retrieval products (effective radius) of bispectral (e.g., MODIS, Moderate Resolution Imaging Spectroradiometer) and polarimetric (e.g., POLDER, Polarization and Directionality of Earth's Reflectances) instruments. However, intercomparisons of airborne bispectral and polarimetric instruments have yielded results that do not appear to be systematically biased relative to one another. Diagnosing this discrepancy is complicated, because it is often difficult for instrument intercomparison studies to isolate differences between retrieval technique sensitivities and specific instrumental differences such as calibration and atmospheric correction. In addition to these technical differences the polarimetric retrieval is also sensitive to the dispersion of the droplet size distribution (effective variance), which could influence the interpretation of the droplet size retrieval. To avoid these instrument-dependent complications, this study makes use of a cloud remote-sensing retrieval simulator. Created by coupling a large-eddy simulation (LES) cloud model with a 1-D radiative transfer model, the simulator serves as a test bed for understanding differences between bispectral and polarimetric retrievals. With the help of this simulator we can not only compare the two techniques to one another (retrieval intercomparison) but also validate retrievals directly against the LES cloud properties. Using the satellite retrieval simulator, we are able to verify that at high spatial resolution (50 m) the bispectral and polarimetric retrievals are highly correlated with one another within expected observational uncertainties. The relatively small systematic biases at high spatial resolution can be attributed to different sensitivity limitations of the two retrievals. In contrast, a systematic difference between the two retrievals emerges at coarser resolution. This bias largely stems from differences related to sensitivity of the two retrievals to unresolved inhomogeneities in effective variance and optical thickness. The influence of coarse angular resolution is found to increase uncertainty in the polarimetric retrieval but generally maintains a constant mean value.

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Section: Model and Methodologymentioning

confidence: 99%

Comparisons of bispectral and polarimetric retrievals of marine boundary layer cloud microphysics: case studies using a LES–satellite retrieval simulator

et al. 2018

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Section: Introductionmentioning

confidence: 99%

“…For example, the intercomparison based on DYCOMS-II demonstrated a substantial range in inter-model surface precipitation rates for the drizzling, stratocumulus-topped boundary layer case (see Ackerman et al, 2009). Ackerman et al (2009) argue that this range results from differences in model dynamics. Although evidence is presented for this claim, the fact that the microphysics and dynamics are coupled in these simulations means that it is difficult to say to what extent the spread can be attributed to the different numerical methods for dynamics alone or interactions between dynamics and microphysics.…”

Section: Introductionmentioning

confidence: 99%

Diagnosis of systematic differences between multiple parametrizations of warm rain microphysics using a kinematic framework

Shipway

Hill

2012

Quart J Royal Meteoro Soc

120

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“…This may explain why the SCM leaves excessive moisture in the sub-cloud layer as compared with SAM LES (see Figure 1(b)). Nevertheless, both SCM profiles of w 2 lie within the range of the LES models (grey shaded region in Figure 1(c)) that participated in the GCSS intercomparison (Ackerman et al, 2009). The vertical velocity variance w 2 indirectly influences rain, but because our simulations specify cloud droplet number it does not directly influence rain.…”

Section: Turbulence Thermodynamic and Cloud Fieldsmentioning

confidence: 69%

“…SAM has successfully performed LES of a variety of boundary layer cases, such as the DYCOMS-II RF01 marine stratocumulus case (Stevens et al, 2005), a trade-wind cumulus case (Siebesma et al, 2003), and a stable boundary layer case (Beare et al, 2006). Of special relevance is the fact that SAM produced comparable output to the other LES models in the recent DYCOMS-II RF02 intercomparison (Ackerman et al, 2009).…”

Section: Les Model: Sammentioning

confidence: 99%

Analytic upscaling of a local microphysics scheme. Part II: Simulations

Griffin

Larson

2012

Quart J Royal Meteoro Soc

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Part I of this two-part series presents a method to account for the effects of subgrid variability on average microphysical process rates. The method involves upscaling a local microphysics scheme, that is, computing a grid-box average by integrating over an assumed probability density function (PDF). In this paper (Part II), the method is tested. The test case is based on research flight two (RF02) of the second Dynamics and Chemistry of Marine Stratocumulus (DYCOMS-II) field experiment. The upscaled microphysics scheme is incorporated into a single-column model (SCM). Then two SCM simulations of the RF02 test case are performed. They are identical except that one upscales the local microphysics scheme and one does not. Both SCM simulations are compared with a benchmark large-eddy simulation (LES) of the same test case using the same local microphysics scheme.Compared to the local microphysics, the representation of variability inherent in the upscaled microphysics increases autoconversion of cloud droplets to raindrops and accretion (i.e. collection) of cloud droplets onto raindrops. The combined effect is that upscaling the microphysics in the RF02 case leads to significantly more rainwater at the ocean surface, in closer agreement to the LES.

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Large-Eddy Simulations of a Drizzling, Stratocumulus-Topped Marine Boundary Layer

Cited by 221 publications

References 71 publications

Comparisons of bispectral and polarimetric retrievals of marine boundary layer cloud microphysics: case studies using a LES–satellite retrieval simulator

Comparisons of bispectral and polarimetric retrievals of marine boundary layer cloud microphysics: case studies using a LES–satellite retrieval simulator

Diagnosis of systematic differences between multiple parametrizations of warm rain microphysics using a kinematic framework

Analytic upscaling of a local microphysics scheme. Part II: Simulations

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