Cloud‐resolving model intercomparison of an MC3E squall line case: Part I—Convective updrafts

Fan, Jiwen; Han, Bin; Varble, Adam; Morrison, Hugh; North, Kirk; Kollias, Pavlos; Chen, Baojun; Dong, Xiquan; Giangrande, Scott; Хаин, А.; Lin, Yun; Mansell, Edward R.; Milbrandt, Jason A.; Stenz, Ronald; Thompson, Gregory; Wang, Yuan

doi:10.1002/2017jd026622

Cited by 126 publications

(120 citation statements)

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“…Although graupel particles in MORR have slightly smaller diameters than THOM above the melting layer, they have faster fall speeds throughout the troposphere (Figure o). Since graupels are primarily produced in convective updrafts (Fan et al, ), they are generally associated with high radar reflectivity due to their high density and large size. Larger and slower falling graupel particles above 6 km in THOM are likely the cause for higher 40‐dBZ echo‐tops in the convective core regions compared to MORR shown in Figure d.…”

Section: Resultsmentioning

confidence: 99%

“…Studies comparing remote sensing and in situ observations with CPM simulations of MCSs show consistent high biases in ice hydrometeor size and their associated radar reflectivity across many commonly used microphysics parameterizations (Stanford et al, ; Varble, Zipser, Fridlind, Zhu, Ackerman, Chaboureau, Collis, et al, ). Comparison of model output to dual‐Doppler radar retrievals in both tropical maritime and midlatitude continental convection indicates that simulated convective‐scale updraft intensities in MCSs are systematically too strong, and stratiform region area and rainfall are consistently underestimated across almost all microphysics parameterizations (Fan et al, ; Varble, Zipser, Fridlind, Zhu, Ackerman, Chaboureau, Fan, et al, ). Because high‐quality simultaneous remote sensing and in situ observations of MCSs are difficult to obtain, they are only available from limited‐duration field campaigns.…”

Section: Introductionmentioning

confidence: 99%

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Structure and Evolution of Mesoscale Convective Systems: Sensitivity to Cloud Microphysics in Convection‐Permitting Simulations Over the United States

Feng

Leung

Houze

et al. 2018

J Adv Model Earth Syst

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Regional climate simulations over the continental United States were conducted for the 2011 warm season using the Weather Research and Forecasting model at convection‐permitting resolution (4 km) with two commonly used microphysics parameterizations (Thompson and Morrison). Sensitivities of the simulated mesoscale convective system (MCS) properties and feedbacks to large‐scale environments are systematically examined against high‐resolution geostationary satellite and 3‐D mosaic radar observations. MCS precipitation including precipitation amount, diurnal cycle, and distribution of hourly precipitation intensity are reasonably captured by the two simulations despite significant differences in their simulated MCS properties. In general, the Thompson simulation produces better agreement with observations for MCS upper level cloud shield and precipitation area, convective feature horizontal and vertical extents, and partitioning between convective and stratiform precipitation. More importantly, Thompson simulates more stratiform rainfall, which agrees better with observations and results in top‐heavier heating profiles from robust MCSs compared to Morrison. A stronger dynamical feedback to the large‐scale environment is therefore seen in Thompson, wherein an enhanced mesoscale vortex behind the MCS strengthens the synoptic‐scale trough and promotes advection of cool and dry air into the rear of the MCS region. The latter prolongs the MCS lifetimes in the Thompson relative to the Morrison simulations. Hence, different treatment of cloud microphysics not only alters MCS convective‐scale dynamics but also has significant impacts on their macrophysical properties such as lifetime and precipitation. As long‐lived MCSs produced 2–3 times the amount of rainfall compared to short‐lived ones, cloud microphysics parameterizations have profound impact in simulating extreme precipitation and the hydrologic cycle.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Structure and Evolution of Mesoscale Convective Systems: Sensitivity to Cloud Microphysics in Convection‐Permitting Simulations Over the United States

Feng

Leung

Houze

et al. 2018

J Adv Model Earth Syst

Self Cite

189

226

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“…

\overset{p}{false}

and

\overset{ρ}{false}

are the mean pressure and air density averaged over domain at a given height for each outputting time, respectively. This calculation follows Fan et al () and Houze () and includes both dynamic and buoyancy sources. The values of PPG at upper levels are negative, associated with the negative vertical gradients of 3‐D divergence (i.e., the dynamic source) and buoyancy (i.e., the buoyancy source).…”

Section: Resultsmentioning

confidence: 99%

Aerosol Impacts on Mesoscale Convective Systems Forming Under Different Vertical Wind Shear Conditions

et al. 2020

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Following our previous study of wind shear effect on mesoscale convective system (MCS) organization under a clean atmospheric condition using the Weather Research and Forecasting model coupled with spectral-bin microphysics, we conduct sensitivity simulations by increasing cloud condensation nuclei concentration to investigate aerosol impacts on MCSs forming under different wind shear conditions. We find that increased aerosols induce stronger updrafts and downdrafts in all MCSs. The stronger updrafts and enlarged convective core area contribute to larger vertical mass fluxes and enhance precipitation. The enhanced updrafts and vertical mass fluxes indicate convective invigoration. Increased updraft speed below 8-km altitude is attributed to enhanced condensational heating, except for the weak wind shear and strong low-level shear cases in which the enhanced low-level convergence is another contributing factor. Interestingly, above 8-km altitude, we see reduced updraft speed by the increased aerosols due to reduced vertical pressure perturbation gradient force. The accumulated rainfall and mean rain rate are increased with a greater occurrence frequency of heavy rain. Larger rain rate is seen in both convective and stratiform regions. In general, we see a higher frequency of deep clouds in the polluted condition because of invigorated convection, and more stratiform/anvil clouds, but a lower frequency of shallow warm clouds, with a larger significance for more organized MCSs. The consistently invigorated MCSs by aerosols under various wind shear conditions revealed by this study have important implications to weather and climate in warm and humid regions that are influenced by pollution.

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“…A single‐moment microphysics parameterization keeps the computational cost of our simulations on a feasible level. However, we note that the choice of the microphysics scheme can influence, for example, in‐cloud properties such as updraft velocities and latent heating, mostly through ice‐related processes (Fan et al, ). Moreover, the representation of ice‐related microphysics can affect the simulated response of extreme precipitation to surface warming (Singh & O'Gorman, ).…”

Section: Conclusion and Discussionmentioning

confidence: 99%

Response of Extreme Precipitating Cell Structures to Atmospheric Warming

2019

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With increasing temperatures, it is likely that precipitation extremes increase as well. While, on larger spatial and longer temporal scales, the amplification of rainfall extremes often follows the Clausius‐Clapeyron relation, it has been shown that local short‐term convective precipitation extremes may well exceed the Clausius‐Clapeyron rate of around 6.5%/K. Most studies on this topic have focused exclusively on the intensity aspect, while only few have examined (with contradictory results) how warmer and moister conditions modulate the spatial characteristics of convective precipitation extremes and how these connect to increased intensities. Here we study this relation by using a large eddy simulation model. We simulate one diurnal cycle of heavy convective precipitation activity based on a realistic observation‐based strongly forced case setup. Systematically perturbed initial conditions of temperature and specific humidity enable an examination of the response of intensities and spatial characteristics of the precipitation field over an 8° dew point temperature range. We find that warmer and moister conditions result in an overall increase of both intensities and spatial extent of individual rain cells. Colder conditions favor the development of many but smaller rain cells. Under warmer conditions, we find a reduced number of individual cells, but their size significantly grows along with an increase of intensities over a large part of a rain cell. Combined, these factors lead to larger and more intense rain cells that can produce up to almost 20% more rain per degree warming and therefore have a large impact.

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Cloud‐resolving model intercomparison of an MC3E squall line case: Part I—Convective updrafts

Cited by 126 publications

References 113 publications

Structure and Evolution of Mesoscale Convective Systems: Sensitivity to Cloud Microphysics in Convection‐Permitting Simulations Over the United States

Structure and Evolution of Mesoscale Convective Systems: Sensitivity to Cloud Microphysics in Convection‐Permitting Simulations Over the United States

Aerosol Impacts on Mesoscale Convective Systems Forming Under Different Vertical Wind Shear Conditions

Response of Extreme Precipitating Cell Structures to Atmospheric Warming

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