Bubble generation mechanisms in microchannel under microgravity and heterogeneous wettability
Bubble generation mechanisms in microchannel under microgravity and heterogeneous wettability
Advances in hybrid surfaces have revealed interesting opportunities for multiphase flow control under microgravity, as the surface tension force is dominant in this condition. However, a comprehensive investigation of bubble generation rates and slug flow parameters remains challenging. This research integrates hybrid wettability and modified dynamic contact angle models to address this important knowledge gap. Using the computational capabilities of the IsoAdvector multiphase method, we performed detailed simulations of complex multiphase flow scenarios with the OpenFOAM package. We then validated these simulation results through rigorous comparison with available experimental data, thereby strengthening the accuracy and reliability of our numerical simulations. Our comprehensive research demonstrates the profound effect of altering contact angle distribution patterns on several critical parameters. These results highlight the precise control that can be achieved through the strategic manipulation of these patterns, offering the possibility of adjusting factors such as bubble production rate, slug length, bubble diameter, the relationship of flow residence to bubble movement, bubble movement speed in the channel, and pressure drop. Interestingly, altering these patterns can also induce asymmetric behavior in bubbles under microgravity conditions, a phenomenon that has significant implications for various applications. Such insights are crucial for fields such as heat transfer in energy systems, reaction mechanisms in chemical processes, multiphase flow control in petrochemical industries, fluid dynamics in aerospace engineering, and cooling mechanisms in electronic devices. With the ability to modulate these fundamental parameters, we gain valuable insights into the design and optimization of microchannel systems. Consequently, this research presents a more efficient and innovative approach to multiphase flow control, promising improved operational performance, and efficiency in various engineering applications.
Mousavi, S. Mahmood
463ebee3-8419-4e14-81d3-6e16598230cc
Lee, Jongkwon
e0b9f1cb-9b39-4262-b898-2078aac0bb5f
Lee, Bok Jik
2980995f-3300-438d-a425-4263e070ee50
Jarrahbashi, Dorrin
369011c3-5565-4493-8265-262b6ae8eef1
Karimi, Nader
620646d6-27c9-4e1e-948f-f23e4a1e773a
Faroughi, Salah A.
6ce82b9f-9d8c-4826-a603-bd34cab53897
23 February 2024
Mousavi, S. Mahmood
463ebee3-8419-4e14-81d3-6e16598230cc
Lee, Jongkwon
e0b9f1cb-9b39-4262-b898-2078aac0bb5f
Lee, Bok Jik
2980995f-3300-438d-a425-4263e070ee50
Jarrahbashi, Dorrin
369011c3-5565-4493-8265-262b6ae8eef1
Karimi, Nader
620646d6-27c9-4e1e-948f-f23e4a1e773a
Faroughi, Salah A.
6ce82b9f-9d8c-4826-a603-bd34cab53897
Mousavi, S. Mahmood, Lee, Jongkwon, Lee, Bok Jik, Jarrahbashi, Dorrin, Karimi, Nader and Faroughi, Salah A.
(2024)
Bubble generation mechanisms in microchannel under microgravity and heterogeneous wettability.
Physics of Fluids, 36 (2), [023351].
(doi:10.1063/5.0188262).
Abstract
Advances in hybrid surfaces have revealed interesting opportunities for multiphase flow control under microgravity, as the surface tension force is dominant in this condition. However, a comprehensive investigation of bubble generation rates and slug flow parameters remains challenging. This research integrates hybrid wettability and modified dynamic contact angle models to address this important knowledge gap. Using the computational capabilities of the IsoAdvector multiphase method, we performed detailed simulations of complex multiphase flow scenarios with the OpenFOAM package. We then validated these simulation results through rigorous comparison with available experimental data, thereby strengthening the accuracy and reliability of our numerical simulations. Our comprehensive research demonstrates the profound effect of altering contact angle distribution patterns on several critical parameters. These results highlight the precise control that can be achieved through the strategic manipulation of these patterns, offering the possibility of adjusting factors such as bubble production rate, slug length, bubble diameter, the relationship of flow residence to bubble movement, bubble movement speed in the channel, and pressure drop. Interestingly, altering these patterns can also induce asymmetric behavior in bubbles under microgravity conditions, a phenomenon that has significant implications for various applications. Such insights are crucial for fields such as heat transfer in energy systems, reaction mechanisms in chemical processes, multiphase flow control in petrochemical industries, fluid dynamics in aerospace engineering, and cooling mechanisms in electronic devices. With the ability to modulate these fundamental parameters, we gain valuable insights into the design and optimization of microchannel systems. Consequently, this research presents a more efficient and innovative approach to multiphase flow control, promising improved operational performance, and efficiency in various engineering applications.
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Accepted/In Press date: 24 January 2024
Published date: 23 February 2024
Identifiers
Local EPrints ID: 509415
URI: http://eprints.soton.ac.uk/id/eprint/509415
ISSN: 1070-6631
PURE UUID: d875f53b-231c-4aa8-83f2-05526d26641a
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Date deposited: 20 Feb 2026 17:47
Last modified: 21 Feb 2026 03:25
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Contributors
Author:
S. Mahmood Mousavi
Author:
Jongkwon Lee
Author:
Bok Jik Lee
Author:
Dorrin Jarrahbashi
Author:
Nader Karimi
Author:
Salah A. Faroughi
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