2010
DOI: 10.1103/physrevlett.105.136102
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Energy Transport by Thermocapillary Convection during Sessile-Water-Droplet Evaporation

Abstract: The energy transport mechanisms of a sessile-water droplet evaporating steadily while maintained on a Cu substrate are compared. Buoyancy-driven convection is eliminated, but thermal conduction and thermocapillary convection are active. The dominant mode varies along the interface. Although neglected in previous studies, near the three-phase line, thermocapillary convection is by far the larger mode of energy transport, and this is the region where most of the droplet evaporation occurs.

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Cited by 88 publications
(112 citation statements)
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“…Our work supports the prediction of Deegan et al (10) that the flow within the droplet arises from mass conservation, since Marangoni convection from the contact line to the apex would lead to higher velocities along the base of the drop than those required to satisfy mass conservation due to evaporation. At first sight it contradicts that of Ghasemi and Ward (4) .…”
Section: Water Dropletsmentioning
confidence: 70%
See 2 more Smart Citations
“…Our work supports the prediction of Deegan et al (10) that the flow within the droplet arises from mass conservation, since Marangoni convection from the contact line to the apex would lead to higher velocities along the base of the drop than those required to satisfy mass conservation due to evaporation. At first sight it contradicts that of Ghasemi and Ward (4) .…”
Section: Water Dropletsmentioning
confidence: 70%
“…Deegan et al (9,10) have studied ring formation from suspension and particle containing water drops, from which they infer that internal flow in the drop is driven by mass conservation to replenish fluid evaporating preferentially at the outer edge of the drop. In contrast, Ghasemi and Ward (4) report that in a reduced pressure environment, flow in evaporating water drops is driven by thermocapillary convection, such as was observed by Buffone et al (11) for a meniscus within a capillary.…”
Section: Introductionmentioning
confidence: 91%
See 1 more Smart Citation
“…The other important characteristic of the DLS is its hydrophilicity, which promotes fluid flow to the surface. The capillary force in the exfoliated graphite layer enhances the evaporation rate of the fluid through several mechanisms: formation of thin films on the surface of graphite sheets 21 , enhanced surface area for evaporation 22 and formation of three-phase contact lines at the edges of the capillaries 23,24 . The graphite structure has hydrophobic surfaces as evidenced by the contact angle ( Supplementary Fig.…”
Section: Resultsmentioning
confidence: 99%
“…The orientation and intensity of this flow in the case of single component drops can depend on the relative thermal properties of the substrate and liquid, Ristenpart et al (2007). Furthermore, these flows can be the result of temperature and/or concentration gradients and may play a major role in energy transport, Ghasemi & Ward (2010). Generally, surface tension driven flows in single component volatile drops are essentially thermocapillary in nature, i.e.…”
Section: Introductionmentioning
confidence: 99%