Vapor-Induced Motion of Liquid Droplets on an Inert Substrate

Xingkun Man; Masao Doi

doi:10.1103/PhysRevLett.119.044502

Vapor-Induced Motion of Liquid Droplets on an Inert Substrate

Xingkun Man^*
, Masao Doi

^*Corresponding author for this work

School of Physics

Beihang University

Research output: Contribution to journal › Article › peer-review

53 Scopus citations

Abstract

Evaporating droplets are known to show complex motion that has conventionally been explained by the Marangoni effect (flow induced by the gradient of surface tension). Here, we show that the droplet motion can be induced even in the absence of the Marangoni effect due to the gradient of the evaporation rate. We derive an equation for the velocity of a droplet subject to the nonuniform evaporation rate and nonuniform surface tension placed on an inert substrate, where the wettability is uniform and unchanged. The equation explains the previously observed attraction-repulsion-chasing behaviors of evaporating droplets.

Original language	English
Article number	044502
Journal	Physical Review Letters
Volume	119
Issue number	4
DOIs	https://doi.org/10.1103/PhysRevLett.119.044502
State	Published - 27 Jul 2017

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10.1103/PhysRevLett.119.044502

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abstract = "Evaporating droplets are known to show complex motion that has conventionally been explained by the Marangoni effect (flow induced by the gradient of surface tension). Here, we show that the droplet motion can be induced even in the absence of the Marangoni effect due to the gradient of the evaporation rate. We derive an equation for the velocity of a droplet subject to the nonuniform evaporation rate and nonuniform surface tension placed on an inert substrate, where the wettability is uniform and unchanged. The equation explains the previously observed attraction-repulsion-chasing behaviors of evaporating droplets.",

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AB - Evaporating droplets are known to show complex motion that has conventionally been explained by the Marangoni effect (flow induced by the gradient of surface tension). Here, we show that the droplet motion can be induced even in the absence of the Marangoni effect due to the gradient of the evaporation rate. We derive an equation for the velocity of a droplet subject to the nonuniform evaporation rate and nonuniform surface tension placed on an inert substrate, where the wettability is uniform and unchanged. The equation explains the previously observed attraction-repulsion-chasing behaviors of evaporating droplets.

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Vapor-Induced Motion of Liquid Droplets on an Inert Substrate

Abstract

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