Occurrence of giant plasma bubble in liquid

Junfeng Wang; Wei Zhang; Tianyi Wu; Menglin Chen; Mingdong Dong

doi:10.1016/j.matt.2024.04.032

Occurrence of giant plasma bubble in liquid

Junfeng Wang^*, Wei Zhang, Tianyi Wu, Menglin Chen, Mingdong Dong^*

^*Corresponding author for this work

Interdisciplinary Nanoscience Center

Research output: Contribution to journal/Conference contribution in journal/Contribution to newspaper › Journal article › Research › peer-review

2 Citations (Scopus)

Abstract

Fluid interfaces are generally known to deform or fragment in accordance with the Rayleigh limit theory under the influence of charged particles. Here, we present experimental evidence of a cross-scale transition from microscopic to macroscopic bubbles in a charged liquid-gas fluid system under a strong electric field. Contrary to predictions based on the Rayleigh limit theory, this phenomenon arises from interactions between ionized matter and natural particles. The resulting plasma bubbles and interfacial phenomena between weakly ionized gas and liquid have significant implications for hydrodynamics and interfacial stability. Our study reveals the relationship between bubble morphology, interface perturbations, and the contribution of electrons and ions to the interface. This discovery of giant plasma bubble generation in liquid unveils a new class of fluid behavior, providing insights into interface physics and interface-enhanced mass transfer in plasma-liquid systems.

Original language	English
Journal	Matter
Volume	7
Issue	9
Pages (from-to)	3024-3035
Number of pages	12
ISSN	2590-2393
DOIs	https://doi.org/10.1016/j.matt.2024.04.032
Publication status	Published - 4 Sept 2024

Keywords

bubble dynamics
charged particles
electrohydrodynamic
interface stability
MAP 1: Discovery
plasma-liquid interface
polarity effect
Rayleigh limit

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title = "Occurrence of giant plasma bubble in liquid",

abstract = "Fluid interfaces are generally known to deform or fragment in accordance with the Rayleigh limit theory under the influence of charged particles. Here, we present experimental evidence of a cross-scale transition from microscopic to macroscopic bubbles in a charged liquid-gas fluid system under a strong electric field. Contrary to predictions based on the Rayleigh limit theory, this phenomenon arises from interactions between ionized matter and natural particles. The resulting plasma bubbles and interfacial phenomena between weakly ionized gas and liquid have significant implications for hydrodynamics and interfacial stability. Our study reveals the relationship between bubble morphology, interface perturbations, and the contribution of electrons and ions to the interface. This discovery of giant plasma bubble generation in liquid unveils a new class of fluid behavior, providing insights into interface physics and interface-enhanced mass transfer in plasma-liquid systems.",

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author = "Junfeng Wang and Wei Zhang and Tianyi Wu and Menglin Chen and Mingdong Dong",

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T1 - Occurrence of giant plasma bubble in liquid

AU - Wang, Junfeng

AU - Zhang, Wei

AU - Wu, Tianyi

AU - Chen, Menglin

AU - Dong, Mingdong

PY - 2024/9/4

Y1 - 2024/9/4

N2 - Fluid interfaces are generally known to deform or fragment in accordance with the Rayleigh limit theory under the influence of charged particles. Here, we present experimental evidence of a cross-scale transition from microscopic to macroscopic bubbles in a charged liquid-gas fluid system under a strong electric field. Contrary to predictions based on the Rayleigh limit theory, this phenomenon arises from interactions between ionized matter and natural particles. The resulting plasma bubbles and interfacial phenomena between weakly ionized gas and liquid have significant implications for hydrodynamics and interfacial stability. Our study reveals the relationship between bubble morphology, interface perturbations, and the contribution of electrons and ions to the interface. This discovery of giant plasma bubble generation in liquid unveils a new class of fluid behavior, providing insights into interface physics and interface-enhanced mass transfer in plasma-liquid systems.

AB - Fluid interfaces are generally known to deform or fragment in accordance with the Rayleigh limit theory under the influence of charged particles. Here, we present experimental evidence of a cross-scale transition from microscopic to macroscopic bubbles in a charged liquid-gas fluid system under a strong electric field. Contrary to predictions based on the Rayleigh limit theory, this phenomenon arises from interactions between ionized matter and natural particles. The resulting plasma bubbles and interfacial phenomena between weakly ionized gas and liquid have significant implications for hydrodynamics and interfacial stability. Our study reveals the relationship between bubble morphology, interface perturbations, and the contribution of electrons and ions to the interface. This discovery of giant plasma bubble generation in liquid unveils a new class of fluid behavior, providing insights into interface physics and interface-enhanced mass transfer in plasma-liquid systems.

KW - bubble dynamics

KW - charged particles

KW - electrohydrodynamic

KW - interface stability

KW - MAP 1: Discovery

KW - plasma-liquid interface

KW - polarity effect

KW - Rayleigh limit

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DO - 10.1016/j.matt.2024.04.032

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JO - Matter

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Occurrence of giant plasma bubble in liquid

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Keywords

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