Surface declination governed asymmetric sessile droplet evaporation

This article reports droplet evaporation kinetics on inclined substrates. Comprehensive experimental and theoretical analyses of the droplet evaporation behavior for different substrate declinations, wettability, and temperatures have been presented. Sessile droplets with substrate declination exhib...

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Published in:Physics of fluids (1994) 2020-11, Vol.32 (11), p.112010
Main Authors: Dhar, Purbarun, Dwivedi, Raghavendra Kumar, Harikrishnan, A. R.
Format: Article
Language:English
Subjects:
Asymmetry
Computational fluid dynamics
Contact angle
Declination
Droplets
Evaporation
Fluid dynamics
Fluid flow
Flux
Kinetics
Particle image velocimetry
Physics
Spherical caps
Substrates
Temperature gradients
Thermohydrodynamics
Velocity measurement
Wettability
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cited_by cdi_FETCH-LOGICAL-c327t-d7987d04f76c868467d9bf1ffd0c4852537e2297e9fed7e90023939e977d682e3
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container_end_page
container_issue 11
container_start_page 112010
container_title Physics of fluids (1994)
container_volume 32
creator Dhar, Purbarun
Dwivedi, Raghavendra Kumar
Harikrishnan, A. R.
description This article reports droplet evaporation kinetics on inclined substrates. Comprehensive experimental and theoretical analyses of the droplet evaporation behavior for different substrate declinations, wettability, and temperatures have been presented. Sessile droplets with substrate declination exhibit a distorted shape and evaporate at different rates compared to droplets on the same horizontal substrate, and exhibit more frequent changes in regimes of evaporation. The slip-stick and jump-stick modes are prominent during evaporation. For droplets on inclined substrates, the evaporative flux is also asymmetric and governed by the initial contact angle dissimilarity. Due to a smaller contact angle at the rear contact line, it is the zone of a higher evaporative flux. Particle image velocimetry shows increased internal circulation velocity within the inclined droplets. Asymmetry in the evaporative flux leads to higher temperature gradients, which ultimately enhances the thermal Marangoni circulation near the rear of the droplet where the evaporative flux is highest. A model is adopted to predict the thermal Marangoni advection velocity, and good match is obtained. The declination angle and imposed thermal conditions compete and lead to morphed evaporation kinetics than those of droplets on horizontal heated surfaces. Even weak movements of the contact line alter the evaporation dynamics significantly, by changing the shape of the droplet from an ideally elliptical to an almost spherical cap, which ultimately reduces the evaporative flux. The lifetime of the droplet is modeled by modifying available models for a non-heated substrate, to account for the shape asymmetry. The present observations may find strong implications toward microscale thermo-hydrodynamics.
doi_str_mv 10.1063/5.0025644
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Particle image velocimetry shows increased internal circulation velocity within the inclined droplets. Asymmetry in the evaporative flux leads to higher temperature gradients, which ultimately enhances the thermal Marangoni circulation near the rear of the droplet where the evaporative flux is highest. A model is adopted to predict the thermal Marangoni advection velocity, and good match is obtained. The declination angle and imposed thermal conditions compete and lead to morphed evaporation kinetics than those of droplets on horizontal heated surfaces. Even weak movements of the contact line alter the evaporation dynamics significantly, by changing the shape of the droplet from an ideally elliptical to an almost spherical cap, which ultimately reduces the evaporative flux. The lifetime of the droplet is modeled by modifying available models for a non-heated substrate, to account for the shape asymmetry. 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Asymmetry in the evaporative flux leads to higher temperature gradients, which ultimately enhances the thermal Marangoni circulation near the rear of the droplet where the evaporative flux is highest. A model is adopted to predict the thermal Marangoni advection velocity, and good match is obtained. The declination angle and imposed thermal conditions compete and lead to morphed evaporation kinetics than those of droplets on horizontal heated surfaces. Even weak movements of the contact line alter the evaporation dynamics significantly, by changing the shape of the droplet from an ideally elliptical to an almost spherical cap, which ultimately reduces the evaporative flux. The lifetime of the droplet is modeled by modifying available models for a non-heated substrate, to account for the shape asymmetry. 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Asymmetry in the evaporative flux leads to higher temperature gradients, which ultimately enhances the thermal Marangoni circulation near the rear of the droplet where the evaporative flux is highest. A model is adopted to predict the thermal Marangoni advection velocity, and good match is obtained. The declination angle and imposed thermal conditions compete and lead to morphed evaporation kinetics than those of droplets on horizontal heated surfaces. Even weak movements of the contact line alter the evaporation dynamics significantly, by changing the shape of the droplet from an ideally elliptical to an almost spherical cap, which ultimately reduces the evaporative flux. The lifetime of the droplet is modeled by modifying available models for a non-heated substrate, to account for the shape asymmetry. 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source American Institute of Physics:Jisc Collections:Transitional Journals Agreement 2021-23 (Reading list); AIP Digital Archive
subjects Asymmetry
Computational fluid dynamics
Contact angle
Declination
Droplets
Evaporation
Fluid dynamics
Fluid flow
Flux
Kinetics
Particle image velocimetry
Physics
Spherical caps
Substrates
Temperature gradients
Thermohydrodynamics
Velocity measurement
Wettability
title Surface declination governed asymmetric sessile droplet evaporation
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