Improving representation of convective transport for scale‐aware parameterization: 1. Convection and cloud properties simulated with spectral bin and bulk microphysics

Fan, Jiwen; Liu, Yi Chin; Xu, Kuan‐Man; North, Kirk; Collis, Scott; Dong, Xiquan; Zhang, Guang J.; Chen, Qian; Kollias, Pavlos; Ghan, Steven J.

doi:10.1002/2014jd022142

Cited by 67 publications

(94 citation statements)

References 86 publications

(175 reference statements)

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“…Finally, in this study, WRF is configured with a single high‐resolution (i.e., 3 km) domain forced by a reanalysis product with a much coarser resolution (i.e., 1°). Similar configurations have been applied by a few other researchers (e.g., Fan et al, ). However, we should admit that the too smooth driving meteorology might restrict the model performance in capturing the fine‐scale surface climate, particularly over areas close to the lateral boundaries, which may further influence the estimated magnitudes of the local effects induced by urbanization.…”

Section: Conclusion and Discussionmentioning

confidence: 92%

Modeling the Impacts of Urbanization on Summer Thermal Comfort: The Role of Urban Land Use and Anthropogenic Heat

Yang

Leung

et al. 2019

JGR Atmospheres

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Urban land use and anthropogenic heat (AH) emission can considerably influence the human thermal comfort during extreme heat events. In this study, a spatially heterogeneous AH emission data and updated urban land use data are integrated into the Weather Research and Forecasting model to simulate the physical processes of urban warming during summer. Simulations conducted in the Yangtze River Delta (YRD) of east China suggest that the mean urban heat island intensity reaches 1.49 °C in urbanized areas during summer, with AH emission making a considerable contribution. The warming effect due to urban land use is intensified during extremely hot days, but in contrast, the AH effects are slightly reduced. Urban development increases the total thermal discomfort hours by 27% in the urban areas of YRD, with AH and urban land use contributing nearly equal amount. By limiting the daytime latent heat release, urban land use reduces the daily maximum heat stress particularly during extremely hot days; however, such alleviations can be offset by the AH emission. Strategies for mitigation of urban heat island effect and heat stress in cities should therefore include measures to reduce AH emission.

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Section: Conclusion and Discussionmentioning

confidence: 92%

Modeling the Impacts of Urbanization on Summer Thermal Comfort: The Role of Urban Land Use and Anthropogenic Heat

Yang

Leung

et al. 2019

JGR Atmospheres

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“…Even within the same dynamical model, results have shown a general sensitivity of CRM deep convection simulations to different cloud microphysics schemes, which often produce large differences in storm structure, dynamics, precipitation, and anvil characteristics [e.g., Li et al ., , ; Morrison et al ., ; Morrison and Milbrandt , ; Fan et al ., ; Khain et al ., ]. This spread of deep convective cloud properties leads to a large uncertainty in assessing aerosol impacts on these clouds as the magnitude and even the sign of changes in updraft strength and surface precipitation with aerosol loading often vary, depending upon the particular model and microphysics parameterization used [e.g., Van den Heever and Cotton , ; Fan et al ., , ; Khain et al ., ].…”

Section: Introductionmentioning

confidence: 99%

“…The squall‐line MCS case simulated in this study occurred on 20 May 2011, during the Midlatitude Continental Convective Clouds Experiment (MC3E) [ Petersen and Jensen , ; Jensen et al ., ], which was supported by both the U.S. Department of Energy Atmospheric Radiation Measurement Program (ARM) and NASA's Global Precipitation Measurement mission ground validation program in north‐central Oklahoma from 22 April to 6 June 2011. Detailed ground‐based and aircraft cloud dynamical and microphysical observations are available for this case [ Mather and Voyles , ; Jensen et al ., ], which has been a focus of several recent studies [e.g., Tao et al ., , ; Giangrande et al ., ; Fan et al ., ; Kumjian et al ., ; Marinescu et al ., ; Van Lier‐Walqui et al ., ; Saleeby et al ., ; Fridlind et al ., ]. Section 2 includes a more detailed description of the case and the relevant observations used in this study.…”

Section: Introductionmentioning

confidence: 99%

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

et al. 2017

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An intercomparison study of a midlatitude mesoscale squall line is performed using the Weather Research and Forecasting (WRF) model at 1 km horizontal grid spacing with eight different cloud microphysics schemes to investigate processes that contribute to the large variability in simulated cloud and precipitation properties. All simulations tend to produce a wider area of high radar reflectivity (Ze > 45 dBZ) than observed but a much narrower stratiform area. The magnitude of the virtual potential temperature drop associated with the gust front passage is similar in simulations and observations, while the pressure rise and peak wind speed are smaller than observed, possibly suggesting that simulated cold pools are shallower than observed. Most of the microphysics schemes overestimate vertical velocity and Ze in convective updrafts as compared with observational retrievals. Simulated precipitation rates and updraft velocities have significant variability across the eight schemes, even in this strongly dynamically driven system. Differences in simulated updraft velocity correlate well with differences in simulated buoyancy and low‐level vertical perturbation pressure gradient, which appears related to cold pool intensity that is controlled by the evaporation rate. Simulations with stronger updrafts have a more optimal convective state, with stronger cold pools, ambient low‐level vertical wind shear, and rear‐inflow jets. Updraft velocity variability between schemes is mainly controlled by differences in simulated ice‐related processes, which impact the overall latent heating rate, whereas surface rainfall variability increases in no‐ice simulations mainly because of scheme differences in collision‐coalescence parameterizations.

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“…One proposal to alleviate this issue is to push climate models to the highest grid‐spacings possible, typically utilizing modern exascale computing systems (Reed & Dongarra, ). This has resulted in a recent surge in research and development addressing multi‐scale modeling (Iorio et al, ; O'Brien et al, ; Tao et al, ), scale‐aware physics (Fan et al, ; Gross et al, ; Herrington & Reed, ; Randall et al, ), and atmospheric models that span hydrostatic and nonhydrostatic scales (Ferguson et al, ; Heinzeller et al, ; Herrington & Reed, ; Park et al, ).…”

Section: Introductionmentioning

confidence: 99%

Sensitivity of Mountain Hydroclimate Simulations in Variable‐Resolution CESM to Microphysics and Horizontal Resolution

Rhoades

Ullrich

Zarzycki

et al. 2018

J Adv Model Earth Syst

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Mountains are natural dams that impede atmospheric moisture transport and water towers that cool, condense, and store precipitation. They are essential in the western United States where precipitation is seasonal, and snowpack is needed to meet water demand. With anthropogenic climate change increasingly threatening mountain snowpack, there is a pressing need to better understand the driving climatological processes. However, the coarse resolution typical of modern global climate models renders them largely insufficient for this task, and signals a need for an advanced strategy. This paper continues the assessment of variable‐resolution in the Community Earth System Model (VR‐CESM) in modeling mountain hydroclimatology to understand the role of grid‐spacing at 55, 28, 14, and 7 km and microphysics, specifically the Morrison and Gettelman (, MG1, https://doi.org/10.1175/2008JCLI2105.1) scheme versus the Gettelman and Morrison (, MG2, https://doi.org/10.1175/JCLI-D-14-00102.1) scheme. Eight VR‐CESM simulations were performed from 1999 to 2015 with the F_AMIP_CAM5 component set, which couples the atmosphere‐land models and prescribes ocean data. Refining horizontal grid‐spacing from 28 to 7 km with the MG1 scheme did not improve the simulated mountain hydroclimatology. Substantial improvements occurred with the use of MG2 at grid‐spacings ≤28 km compared to MG1 as shown with subsequent statistics. Average SWE bias diminished by 9.4X, 4.9X, and 3.5X from 55 to 7 km. The range in minimum (maximum) DJF spatial correlations increased by 0.1–0.2 in both precipitation and SWE. Mountain windward/leeward distributions and elevation profiles improved across hydroclimate variables, however not always with model resolution alone. Disconcertingly, all VR‐CESM simulations exhibited a systemic mountain cold bias that worsened with elevation and will require further examination.

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Improving representation of convective transport for scale‐aware parameterization: 1. Convection and cloud properties simulated with spectral bin and bulk microphysics

Cited by 67 publications

References 86 publications

Modeling the Impacts of Urbanization on Summer Thermal Comfort: The Role of Urban Land Use and Anthropogenic Heat

Modeling the Impacts of Urbanization on Summer Thermal Comfort: The Role of Urban Land Use and Anthropogenic Heat

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

Sensitivity of Mountain Hydroclimate Simulations in Variable‐Resolution CESM to Microphysics and Horizontal Resolution

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