Impact of hybrid surfaces on the droplet breakup dynamics in microgravity slug flow: a dynamic contact angle analysis
Impact of hybrid surfaces on the droplet breakup dynamics in microgravity slug flow: a dynamic contact angle analysis
Microfluidic devices, which enable precise control and manipulation of fluids at the microscale, have revolutionized various fields, including chemical synthesis and space technology. A comprehensive understanding of fluid behavior under diverse conditions, particularly in microgravity, is essential for optimizing the design and performance of these devices. This paper aims to investigate the effects of discontinuous wettability on droplet breakup structures under microgravity conditions using a microchannel wall. The approach we adopt is underpinned by the volume-of-fluid methodology, an efficient technique renowned for its accurate resolution of the fluid interface in a two-phase flow. Furthermore, a modified dynamic contact angle model is employed to precisely predict the shape of the droplet interface at and near the wall. Our comprehensive model considers influential parameters such as slug length and droplet generation frequency, thereby providing crucial insights into their impact on the two-phase interface velocity. Validated against existing literature data, our model explores the impact of various configurations of discontinuous wettability on breakup morphology. Our findings highlight the significance of employing a dynamic contact angle methodology for making accurate predictions of droplet shape, which is influenced by the wall contact angle. Emphasis is placed particularly on the effects of slug length and droplet generation frequency. Notably, we demonstrate that the use of a hybrid surface at the junction section allows for precise control over the shape and size of the daughter droplets, contrasting with the symmetrical division observed on uniformly hydrophilic or superhydrophobic surfaces. This study contributes valuable insights into the complex dynamics of the droplet breakup process, which has profound implications for the design and optimization of microfluidic devices operating under microgravity conditions. Such insights are further poised to augment applications in space exploration, microreactors, and more.</jats:p>
Mousavi, S. Mahmood
81fe233c-20e0-4168-9fac-2acd106b5aad
Jarrahbashi, Dorrin
7d654c6a-9936-4e81-bef3-60d89937c253
Lee, Bok Jik
2980995f-3300-438d-a425-4263e070ee50
Karimi, Nader
620646d6-27c9-4e1e-948f-f23e4a1e773a
Faroughi, Salah A.
bbdf4c8b-042e-454c-9ab7-f6eb81c4d6ab
5 July 2023
Mousavi, S. Mahmood
81fe233c-20e0-4168-9fac-2acd106b5aad
Jarrahbashi, Dorrin
7d654c6a-9936-4e81-bef3-60d89937c253
Lee, Bok Jik
2980995f-3300-438d-a425-4263e070ee50
Karimi, Nader
620646d6-27c9-4e1e-948f-f23e4a1e773a
Faroughi, Salah A.
bbdf4c8b-042e-454c-9ab7-f6eb81c4d6ab
Mousavi, S. Mahmood, Jarrahbashi, Dorrin, Lee, Bok Jik, Karimi, Nader and Faroughi, Salah A.
(2023)
Impact of hybrid surfaces on the droplet breakup dynamics in microgravity slug flow: a dynamic contact angle analysis.
Physics of Fluids, 35 (7), [072003].
(doi:10.1063/5.0159118).
Abstract
Microfluidic devices, which enable precise control and manipulation of fluids at the microscale, have revolutionized various fields, including chemical synthesis and space technology. A comprehensive understanding of fluid behavior under diverse conditions, particularly in microgravity, is essential for optimizing the design and performance of these devices. This paper aims to investigate the effects of discontinuous wettability on droplet breakup structures under microgravity conditions using a microchannel wall. The approach we adopt is underpinned by the volume-of-fluid methodology, an efficient technique renowned for its accurate resolution of the fluid interface in a two-phase flow. Furthermore, a modified dynamic contact angle model is employed to precisely predict the shape of the droplet interface at and near the wall. Our comprehensive model considers influential parameters such as slug length and droplet generation frequency, thereby providing crucial insights into their impact on the two-phase interface velocity. Validated against existing literature data, our model explores the impact of various configurations of discontinuous wettability on breakup morphology. Our findings highlight the significance of employing a dynamic contact angle methodology for making accurate predictions of droplet shape, which is influenced by the wall contact angle. Emphasis is placed particularly on the effects of slug length and droplet generation frequency. Notably, we demonstrate that the use of a hybrid surface at the junction section allows for precise control over the shape and size of the daughter droplets, contrasting with the symmetrical division observed on uniformly hydrophilic or superhydrophobic surfaces. This study contributes valuable insights into the complex dynamics of the droplet breakup process, which has profound implications for the design and optimization of microfluidic devices operating under microgravity conditions. Such insights are further poised to augment applications in space exploration, microreactors, and more.</jats:p>
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Accepted/In Press date: 13 June 2023
Published date: 5 July 2023
Identifiers
Local EPrints ID: 508999
URI: http://eprints.soton.ac.uk/id/eprint/508999
ISSN: 1070-6631
PURE UUID: 7d1cdc55-c150-4fa3-bd2d-0837ab1f8090
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Date deposited: 10 Feb 2026 17:30
Last modified: 11 Feb 2026 03:18
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Author:
S. Mahmood Mousavi
Author:
Dorrin Jarrahbashi
Author:
Bok Jik Lee
Author:
Nader Karimi
Author:
Salah A. Faroughi
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