Characterization of Surface Heterogeneity‐Induced Convection Using Cluster Analysis

Chen, J.; Hagos, Samson; Xiao, Heng; Fast, Jerome D.; Feng, Zhe

doi:10.1029/2020jd032550

Cited by 13 publications

(27 citation statements)

References 44 publications

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“…We limit our analysis to the time period between 1000 and 1100 CST; specifically, we evaluate the average of 1000, 1015, 1030, and 1045 CST instantaneous outputs, referred to as the “1000 CST period” in the following. This is when the average z i already grows to be ∼1.5 km, an equilibrium height that remains the same in the afternoon, while clouds have not matured yet at this time to obscure the forcing from the surface to the atmosphere (Chen et al., 2020; Fast, Berg, Feng et al., 2019).…”

Section: Resultsmentioning

confidence: 99%

“…It is important to retain the same land cover as Fast, Berg, Feng et al (2019) because strong dependence of evaporative fraction on the vegetation cover has been suggested for the SGP site (Williams & Torn, 2015). Readers are also referred to Chen et al (2020) for the influence of land cover heterogeneity on the cloud development for the same HI-SCALE case. Surface topography is another important forcing, which we exclude from our main simulations to interpret atmospheric response to the imposed surface heterogeneities without other confounding effects.…”

Section: Tablementioning

confidence: 99%

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Determining Spatial Scales of Soil Moisture—Cloud Coupling Pathways Using Semi‐Idealized Simulations

et al. 2022

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Soil moisture (SM) is an important component of the land-atmosphere (L-A) system. SM changes how available energy at the land surface is partitioned between sensible and latent heat fluxes, which in turn affects the buoyancy of the near-surface air parcels and the growth of the atmospheric boundary layer (BL). For subtropical and mid-latitude continents in the warm season, surface evapotranspiration originating from SM can be an important source for atmospheric moisture. Both the BL growth and atmospheric moisture affect cloud development and precipitation, which then changes the water and energy fluxes into the surface, forming a feedback loop (Betts, 2004;D'Odorico & Porporato, 2004;Koster et al., 2003).Spatial heterogeneity of surface characteristics can induce thermally forced secondary circulations in the BL (e.g., Pielke et al., 1991;Segal & Arritt, 1992;Taylor et al., 2012). The associated upward motions transport moisture to the free troposphere to facilitate cloud formation. Although background winds or other surface forcing can dominate over such secondary circulations (e.g., Avissar & Schmidt, 1998;Lee et al., 2019;Shaw & Doran, 2001), given the very limited predictability of turbulent flow and moist convection, spatiotemporal distributions of surface forcing are still valuable to help constrain the initiation and development of convective systems (Yano et al., 2018). Several studies demonstrated the potential of the knowledge of SM distributions to improve skills of weather and seasonal forecasts (Beljaars et al., 1996;Koster et al., 2010;Xue et al., 2001). Because of the feedback through the hydrological and energy cycles, SM plays an important role in the climate time scale as well, including large-scale monsoon circulations (e.g.,

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Section: Resultsmentioning

confidence: 99%

Section: Tablementioning

confidence: 99%

Determining Spatial Scales of Soil Moisture—Cloud Coupling Pathways Using Semi‐Idealized Simulations

et al. 2022

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“…The median shows more intense radiative cooling during the ShCu regime than for ShDeep. For example, Edwards et al (2014), using large-eddy simulations, showed that radiative cooling has an important effect on the morning transition and in the development of the convective BL. The mechanical turbulence is seen in Fig.…”

Section: Event Datementioning

confidence: 99%

Morning boundary layer conditions for shallow to deep convective cloud evolution during the dry season in the central Amazon

et al. 2021

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Abstract. Observations of the boundary layer (BL) processes are analyzed statistically for dry seasons of 2 years and in detail, as case studies, for 4 shallow convective days (ShCu) and 4 shallow-to-deep convective days (ShDeep) using a suite of ground-based measurements from the Observation and Modeling of the Green Ocean Amazon (GoAmazon 2014/5) Experiment. The BL stages in ShDeep days, from the nighttime to the cloudy mixing layer stage, are then described in comparison with ShCu days. Atmospheric thermodynamics and dynamics, environmental profiles, and surface turbulent fluxes were employed to compare these two distinct situations for each stage of the BL evolution. Particular attention is given to the morning transition stage, in which the BL changes from stable to unstable conditions in the early morning hours. Results show that the decrease in time duration of the morning transition on ShDeep days is associated with high humidity and well-established vertical wind shear patterns. Higher humidity since nighttime not only contributes to lowering the cloud base during the rapid growth of the BL but also contributes to the balance between radiative cooling and turbulent mixing during nighttime, resulting in higher sensible heat flux in the early morning. The sensible heat flux promotes rapid growth of the well-mixed layer, thus favoring the deeper BL starting from around 08:00 LST (UTC−4 h). Under these conditions, the time duration of morning transition is used to promote convection, having an important effect on the convective BL strength and leading to the formation of shallow cumulus clouds and their subsequent evolution into deep convective clouds. Statistical analysis was used to validate the conceptual model obtained from the case studies. Despite the case-to-case variability, the statistical analyses of the processes in the BL show that the described processes are very representative of cloud evolution during the dry season.

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“…Continental shallow cumulus clouds (ShCu) are tightly coupled with the land surface and have strong impacts on the surface energy partition and the turbulent transport of momentum, heat, and moisture [1][2][3][4][5][6]. They are also important for their seeding role in transitioning into hot-tower deep convective clouds with heavy precipitation [7].…”

Section: Introductionmentioning

confidence: 99%

“…2021, 13, 2309 2 of 19 albedos, surface roughness, soil moisture content, and leaf area index. This is because: (1) ShCu strongly interact with the surface heating and moistening driven by the diurnally varying solar and infrared radiation; (2) observations of the initiation and continuous development of ShCu are needed to study the mechanisms controlling the transition from shallow to deep convection; (3) cloud size is important as larger clouds can grow deep and rain more easily [17]; and (4) ShCu may form preferentially over certain land surface properties or land cover types [18,19].…”

Section: Introductionmentioning

confidence: 99%

Summertime Continental Shallow Cumulus Cloud Detection Using GOES-16 Satellite and Ground-Based Stereo Cameras at the DOE ARM Southern Great Plains Site

et al. 2021

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Summertime continental shallow cumulus clouds (ShCu) are detected using Geostationary Operational Environmental Satellite (GOES)-16 reflectance data, with cross-validation by observations from ground-based stereo cameras at the Department of Energy Atmospheric Radiation Measurement Southern Great Plains site. A ShCu cloudy pixel is identified when the GOES reflectance exceeds the clear-sky surface reflectance by a reflectance detection threshold of ShCu, ΔR. We firstly construct diurnally varying clear-sky surface reflectance maps and then estimate the ∆R. A GOES simulator is designed, projecting the clouds reconstructed by stereo cameras towards the surface along the satellite’s slanted viewing direction. The dynamic ShCu detection threshold ΔR is determined by making the GOES cloud fraction (CF) equal to the CF from the GOES simulator. Although there are temporal variabilities in ΔR, cloud fractions and cloud size distributions can be well reproduced using a constant ΔR value of 0.045. The method presented in this study enables daytime ShCu detection, which is usually falsely reported as clear sky in the GOES-16 cloud mask data product. Using this method, a new ShCu dataset can be generated to bridge the observational gap in detecting ShCu, which may transition into deep precipitating clouds, and to facilitate further studies on ShCu development over heterogenous land surface.

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Characterization of Surface Heterogeneity‐Induced Convection Using Cluster Analysis

Cited by 13 publications

References 44 publications

Determining Spatial Scales of Soil Moisture—Cloud Coupling Pathways Using Semi‐Idealized Simulations

Determining Spatial Scales of Soil Moisture—Cloud Coupling Pathways Using Semi‐Idealized Simulations

Morning boundary layer conditions for shallow to deep convective cloud evolution during the dry season in the central Amazon

Summertime Continental Shallow Cumulus Cloud Detection Using GOES-16 Satellite and Ground-Based Stereo Cameras at the DOE ARM Southern Great Plains Site

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