Self-Similar Relaxation of Confined Microfluidic Droplets

Margaux Kerdraon; Joshua D. McGraw; Benjamin Dollet; Marie Caroline Jullien

doi:10.1103/PhysRevLett.123.024501

Self-Similar Relaxation of Confined Microfluidic Droplets

Margaux Kerdraon, Joshua D. McGraw, Benjamin Dollet, Marie Caroline Jullien

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

Abstract

We report an experimental study concerning the capillary relaxation of a confined liquid droplet in a microscopic channel with a rectangular cross section. The confinement leads to a droplet that is extended along the direction normal to the cross section. These droplets, found in numerous microfluidic applications, are pinched into a peanutlike shape thanks to a localized, reversible deformation of the channel. Once the channel deformation is released, the droplet relaxes back to a pluglike shape. During this relaxation, the liquid contained in the central pocket drains towards the extremities of the droplet. Modeling such viscocapillary droplet relaxation requires considering the problem as 3D due to confinement. This 3D consideration yields a scaling model incorporating dominant dissipation within the droplet menisci. As such, the self-similar droplet dynamics is fully captured.

Original language	English
Article number	024501
Journal	Physical Review Letters
Volume	123
Issue number	2
DOIs	https://doi.org/10.1103/PhysRevLett.123.024501
Publication status	Published - 9 Jul 2019
Externally published	Yes

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10.1103/PhysRevLett.123.024501

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title = "Self-Similar Relaxation of Confined Microfluidic Droplets",

abstract = "We report an experimental study concerning the capillary relaxation of a confined liquid droplet in a microscopic channel with a rectangular cross section. The confinement leads to a droplet that is extended along the direction normal to the cross section. These droplets, found in numerous microfluidic applications, are pinched into a peanutlike shape thanks to a localized, reversible deformation of the channel. Once the channel deformation is released, the droplet relaxes back to a pluglike shape. During this relaxation, the liquid contained in the central pocket drains towards the extremities of the droplet. Modeling such viscocapillary droplet relaxation requires considering the problem as 3D due to confinement. This 3D consideration yields a scaling model incorporating dominant dissipation within the droplet menisci. As such, the self-similar droplet dynamics is fully captured.",

author = "Margaux Kerdraon and McGraw, \{Joshua D.\} and Benjamin Dollet and Jullien, \{Marie Caroline\}",

note = "Publisher Copyright: {\textcopyright} 2019 American Physical Society.",

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AU - McGraw, Joshua D.

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AU - Jullien, Marie Caroline

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AB - We report an experimental study concerning the capillary relaxation of a confined liquid droplet in a microscopic channel with a rectangular cross section. The confinement leads to a droplet that is extended along the direction normal to the cross section. These droplets, found in numerous microfluidic applications, are pinched into a peanutlike shape thanks to a localized, reversible deformation of the channel. Once the channel deformation is released, the droplet relaxes back to a pluglike shape. During this relaxation, the liquid contained in the central pocket drains towards the extremities of the droplet. Modeling such viscocapillary droplet relaxation requires considering the problem as 3D due to confinement. This 3D consideration yields a scaling model incorporating dominant dissipation within the droplet menisci. As such, the self-similar droplet dynamics is fully captured.

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Self-Similar Relaxation of Confined Microfluidic Droplets

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