The asymmetric coalescence of two droplets with different surface tensions is caused by capillary waves

Michiel A. Hack; Patrick Vondeling; Menno Cornelissen; Detlef Lohse; Jacco H. Snoeijer; Christian Diddens; Tim Segers

doi:10.48550/arXiv.2201.04201

The asymmetric coalescence of two droplets with different surface tensions is caused by capillary waves

Michiel A. Hack, Patrick Vondeling, Menno Cornelissen, Detlef Lohse, Jacco H. Snoeijer, Christian Diddens, Tim Segers

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Abstract

When two droplets with different surface tensions collide, the shape evolution of the merging droplets is asymmetric. Using experimental and numerical techniques, we reveal that this asymmetry is caused by asymmetric capillary waves, which are the result of the different surface tensions of the droplets. We show that the asymmetry is enhanced by increasing the surface tension difference, and suppressed by increasing the inertia of the colliding droplets. Furthermore, we study capillary waves in the limit of no inertia. We reveal that the asymmetry is not directly caused by Marangoni forces. In fact, somehow counterintuitive, asymmetry is strongly reduced by the Marangoni effect. Rather, the different intrinsic capillary wave amplitudes and velocities associated with the different surface tensions of the droplets lie at the origin of the asymmetry during droplet coalescence.

Original language	English
Publisher	ArXiv.org
Number of pages	23
DOIs	https://doi.org/10.48550/arXiv.2201.04201
Publication status	Published - 11 Jan 2022

Keywords

physics.flu-dyn

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Asymmetric coalescence of two droplets with different surface tensions is caused by capillary waves
Hack, M. A., Vondeling, P., Cornelissen, M., Lohse, D., Snoeijer, J. H., Diddens, C. & Segers, T., Oct 2021, In: Physical review fluids. 6, 10, 104002.
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title = "The asymmetric coalescence of two droplets with different surface tensions is caused by capillary waves",

abstract = " When two droplets with different surface tensions collide, the shape evolution of the merging droplets is asymmetric. Using experimental and numerical techniques, we reveal that this asymmetry is caused by asymmetric capillary waves, which are the result of the different surface tensions of the droplets. We show that the asymmetry is enhanced by increasing the surface tension difference, and suppressed by increasing the inertia of the colliding droplets. Furthermore, we study capillary waves in the limit of no inertia. We reveal that the asymmetry is not directly caused by Marangoni forces. In fact, somehow counterintuitive, asymmetry is strongly reduced by the Marangoni effect. Rather, the different intrinsic capillary wave amplitudes and velocities associated with the different surface tensions of the droplets lie at the origin of the asymmetry during droplet coalescence. ",

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AU - Hack, Michiel A.

AU - Vondeling, Patrick

AU - Cornelissen, Menno

AU - Lohse, Detlef

AU - Snoeijer, Jacco H.

AU - Diddens, Christian

AU - Segers, Tim

N1 - 23 pages, 12 figures, submitted version (final version published in Phys. Rev. Fluids)

PY - 2022/1/11

Y1 - 2022/1/11

N2 - When two droplets with different surface tensions collide, the shape evolution of the merging droplets is asymmetric. Using experimental and numerical techniques, we reveal that this asymmetry is caused by asymmetric capillary waves, which are the result of the different surface tensions of the droplets. We show that the asymmetry is enhanced by increasing the surface tension difference, and suppressed by increasing the inertia of the colliding droplets. Furthermore, we study capillary waves in the limit of no inertia. We reveal that the asymmetry is not directly caused by Marangoni forces. In fact, somehow counterintuitive, asymmetry is strongly reduced by the Marangoni effect. Rather, the different intrinsic capillary wave amplitudes and velocities associated with the different surface tensions of the droplets lie at the origin of the asymmetry during droplet coalescence.

AB - When two droplets with different surface tensions collide, the shape evolution of the merging droplets is asymmetric. Using experimental and numerical techniques, we reveal that this asymmetry is caused by asymmetric capillary waves, which are the result of the different surface tensions of the droplets. We show that the asymmetry is enhanced by increasing the surface tension difference, and suppressed by increasing the inertia of the colliding droplets. Furthermore, we study capillary waves in the limit of no inertia. We reveal that the asymmetry is not directly caused by Marangoni forces. In fact, somehow counterintuitive, asymmetry is strongly reduced by the Marangoni effect. Rather, the different intrinsic capillary wave amplitudes and velocities associated with the different surface tensions of the droplets lie at the origin of the asymmetry during droplet coalescence.

KW - physics.flu-dyn

U2 - 10.48550/arXiv.2201.04201

DO - 10.48550/arXiv.2201.04201

M3 - Preprint

BT - The asymmetric coalescence of two droplets with different surface tensions is caused by capillary waves

PB - ArXiv.org

ER -

The asymmetric coalescence of two droplets with different surface tensions is caused by capillary waves

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Asymmetric coalescence of two droplets with different surface tensions is caused by capillary waves

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