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Impact of high- and low-vorticity turbulence on cloud–environment mixing and cloud microphysics processes

Bipin Kumar, Rahul Ranjan, Man‐Kong Yau, Sudarsan Bera, Suryachandra A. Rao

2021Atmospheric chemistry and physics14 citationsDOIOpen Access PDF

Abstract

Abstract. Turbulent mixing of dry air affects the evolution of the cloud droplet size spectrum via various mechanisms. In a turbulent cloud, high- and low-vorticity regions coexist, and inertial clustering of cloud droplets can occur in low-vorticity regions. The nonuniformity in the spatial distribution of the size and in the number of droplets, variable vertical velocity in vortical turbulent structures, and dilution by entrainment/mixing may result in spatial supersaturation variability, which affects the evolution of the cloud droplet size spectrum via condensation and evaporation processes. To untangle the processes involved in mixing phenomena, a 3D direct numerical simulation of turbulent mixing followed by droplet evaporation/condensation in a submeter-sized cubed domain consisting of a large number of droplets was performed in this study. The analysis focused on the thermodynamic and microphysical characteristics of the droplets and the flow in high- and low-vorticity regions. The impact of vorticity generation in turbulent flows on mixing and cloud microphysics is illustrated.

Topics & Concepts

VorticityTurbulenceMixing (physics)MechanicsEntrainment (biomusicology)MeteorologyCloud physicsCondensationPhysicsAtmospheric sciencesEnvironmental scienceVortexCloud computingAcousticsOperating systemComputer scienceQuantum mechanicsRhythmParticle Dynamics in Fluid FlowsAeolian processes and effectsAtmospheric aerosols and clouds
Impact of high- and low-vorticity turbulence on cloud–environment mixing and cloud microphysics processes | Litcius