Thermocapillary motion on lubricant-impregnated surfaces

Nada Bjelobrk; Henri Louis Girard; Srinivas Bengaluru Subramanyam; Hyuk Min Kwon; David Quéré; Kripa K. Varanasi

doi:10.1103/PhysRevFluids.1.063902

Thermocapillary motion on lubricant-impregnated surfaces

Nada Bjelobrk
, Henri Louis Girard
, Srinivas Bengaluru Subramanyam
, Hyuk Min Kwon
, David Quéré
, Kripa K. Varanasi

Massachusetts Institute of Technology
UMR 7636 CNRS-ESPCI ParisTech-Université Pierre et Marie Curie

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

Abstract

We show that thermocapillary-induced droplet motion is markedly enhanced when using lubricant-impregnated surfaces as compared to solid substrates. These surfaces provide weak pinning, which makes them ideal for droplet transportation and specifically for water transportation. Using a lubricant with viscosity comparable to that of water and temperature gradients as low as 2 K/mm, we observe that drops can propel at 6.5 mm/s, that is, at least 5 times quicker than reported on conventional substrates. Also in contrast with solids, the liquid nature of the different interfaces makes it possible to predict quantitatively the thermocapillary Marangoni force (and velocity) responsible for the propulsion.

Original language	English
Article number	063902
Journal	Physical Review Fluids
Volume	1
Issue number	6
DOIs	https://doi.org/10.1103/PhysRevFluids.1.063902
Publication status	Published - 1 Oct 2016
Externally published	Yes

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10.1103/PhysRevFluids.1.063902

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title = "Thermocapillary motion on lubricant-impregnated surfaces",

abstract = "We show that thermocapillary-induced droplet motion is markedly enhanced when using lubricant-impregnated surfaces as compared to solid substrates. These surfaces provide weak pinning, which makes them ideal for droplet transportation and specifically for water transportation. Using a lubricant with viscosity comparable to that of water and temperature gradients as low as 2 K/mm, we observe that drops can propel at 6.5 mm/s, that is, at least 5 times quicker than reported on conventional substrates. Also in contrast with solids, the liquid nature of the different interfaces makes it possible to predict quantitatively the thermocapillary Marangoni force (and velocity) responsible for the propulsion.",

author = "Nada Bjelobrk and Girard, \{Henri Louis\} and Subramanyam, \{Srinivas Bengaluru\} and Kwon, \{Hyuk Min\} and David Qu{\'e}r{\'e} and Varanasi, \{Kripa K.\}",

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doi = "10.1103/PhysRevFluids.1.063902",

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AU - Bjelobrk, Nada

AU - Girard, Henri Louis

AU - Subramanyam, Srinivas Bengaluru

AU - Kwon, Hyuk Min

AU - Quéré, David

AU - Varanasi, Kripa K.

PY - 2016/10/1

Y1 - 2016/10/1

N2 - We show that thermocapillary-induced droplet motion is markedly enhanced when using lubricant-impregnated surfaces as compared to solid substrates. These surfaces provide weak pinning, which makes them ideal for droplet transportation and specifically for water transportation. Using a lubricant with viscosity comparable to that of water and temperature gradients as low as 2 K/mm, we observe that drops can propel at 6.5 mm/s, that is, at least 5 times quicker than reported on conventional substrates. Also in contrast with solids, the liquid nature of the different interfaces makes it possible to predict quantitatively the thermocapillary Marangoni force (and velocity) responsible for the propulsion.

AB - We show that thermocapillary-induced droplet motion is markedly enhanced when using lubricant-impregnated surfaces as compared to solid substrates. These surfaces provide weak pinning, which makes them ideal for droplet transportation and specifically for water transportation. Using a lubricant with viscosity comparable to that of water and temperature gradients as low as 2 K/mm, we observe that drops can propel at 6.5 mm/s, that is, at least 5 times quicker than reported on conventional substrates. Also in contrast with solids, the liquid nature of the different interfaces makes it possible to predict quantitatively the thermocapillary Marangoni force (and velocity) responsible for the propulsion.

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DO - 10.1103/PhysRevFluids.1.063902

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JO - Physical Review Fluids

JF - Physical Review Fluids

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ER -

Thermocapillary motion on lubricant-impregnated surfaces

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