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Modeling Unsteady Bénard-Marangoni Instabilities in Drying Volatile Droplets on a Heated Substrate

A. A. Gavrilina, L. Yu. Barash

2021Journal of Experimental and Theoretical Physics10 citationsDOIOpen Access PDF

Abstract

Abstract We study unsteady internal flows in a sessile droplet of capillary size evaporating in constant contact line mode on a heated substrate. Three-dimensional simulations of internal flows in evaporating droplets of ethanol and silicone oil have been carried out. For describing the Marangoni flows we find it necessary to account for the diffusion of vapor in air, the thermal conduction in all three phases and thermal radiation. The equations have been solved numerically by finite element method using ANSYS Fluent. As a result of the simulations, the nonstationary behavior of Bénard-Marangoni (BM) instabilities is obtained. At the first stage, a flower structure of BM cells near the triple line emerge. For smaller contact angles, the cells grow in size and occupy the central region of the droplet surface. Being closely connected with recent experimental and theoretical studies, the results obtained help to analyze and resolve the associated issues.

Topics & Concepts

Marangoni effectMaterials scienceThermal conductionMechanicsCapillary actionThermalSilicone oilSubstrate (aquarium)EvaporationDiffusionInternal heatingLine (geometry)ThermodynamicsFinite element methodHeat transferComposite materialMode (computer interface)ConvectionContact angleTransient (computer programming)SPHERESMatrix (chemical analysis)MetastabilityElectrohydrodynamicsWater vaporVaporizationOil dropletLeidenfrost effectConstant (computer programming)ThermophoresisFick's laws of diffusionNanomaterials and Printing TechnologiesFluid Dynamics and Thin FilmsFluid Dynamics and Heat Transfer
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