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Purely irrotational theories for the viscous effects on the oscillations of drops and bubbles

Purely irrotational theories for the viscous effects on the oscillations of drops and bubbles
Purely irrotational theories for the viscous effects on the oscillations of drops and bubbles

In this paper, we apply two purely irrotational theories of the motion of a viscous fluid, namely, viscous potential flow (VPF) and the dissipation method to the problem of the decay of waves on the surface of a sphere. We treat the problem of the decay of small disturbances on a viscous drop surrounded by gas of negligible density and viscosity and a bubble immersed in a viscous liquid. The instantaneous velocity field in the viscous liquid is assumed to be irrotational. In VPF, viscosity enters the problem through the viscous normal stress at the free surface. In the dissipation method, viscosity appears in the dissipation integral included in the mechanical energy equation. Comparisons of the eigenvalues from VPF and the dissipation approximation with those from the exact solution of the linearized governing equations are presented. The results show that the viscous irrotational theories exhibit most of the features of the wave dynamics described by the exact solution. In particular, VPF and DM give rise to a viscous correction for the frequency that determines the crossover from oscillatory to monotonically decaying waves. Good to reasonable quantitative agreement with the exact solution is also shown for certain ranges of modes and dimensionless viscosity: For large viscosity and short waves, VPF is a very good approximation to the exact solution. For 'small' viscosity and long waves, the dissipation method furnishes the best approximation.

Bubbles, Drops, Gas-liquid flow, Potential flow, Two-phase flow, Viscous potential flow
0301-9322
61-75
Padrino, J.C.
961f9d2a-ee9d-4619-a267-2bf098612978
Funada, T.
010aba83-2810-4b94-b1a9-bb87431b9a89
Joseph, D.D.
fda3580e-d34a-488d-b4fb-ba1f10de1020
Padrino, J.C.
961f9d2a-ee9d-4619-a267-2bf098612978
Funada, T.
010aba83-2810-4b94-b1a9-bb87431b9a89
Joseph, D.D.
fda3580e-d34a-488d-b4fb-ba1f10de1020

Padrino, J.C., Funada, T. and Joseph, D.D. (2008) Purely irrotational theories for the viscous effects on the oscillations of drops and bubbles. International Journal of Multiphase Flow, 34 (1), 61-75. (doi:10.1016/j.ijmultiphaseflow.2007.06.008).

Record type: Article

Abstract

In this paper, we apply two purely irrotational theories of the motion of a viscous fluid, namely, viscous potential flow (VPF) and the dissipation method to the problem of the decay of waves on the surface of a sphere. We treat the problem of the decay of small disturbances on a viscous drop surrounded by gas of negligible density and viscosity and a bubble immersed in a viscous liquid. The instantaneous velocity field in the viscous liquid is assumed to be irrotational. In VPF, viscosity enters the problem through the viscous normal stress at the free surface. In the dissipation method, viscosity appears in the dissipation integral included in the mechanical energy equation. Comparisons of the eigenvalues from VPF and the dissipation approximation with those from the exact solution of the linearized governing equations are presented. The results show that the viscous irrotational theories exhibit most of the features of the wave dynamics described by the exact solution. In particular, VPF and DM give rise to a viscous correction for the frequency that determines the crossover from oscillatory to monotonically decaying waves. Good to reasonable quantitative agreement with the exact solution is also shown for certain ranges of modes and dimensionless viscosity: For large viscosity and short waves, VPF is a very good approximation to the exact solution. For 'small' viscosity and long waves, the dissipation method furnishes the best approximation.

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More information

e-pub ahead of print date: 20 July 2007
Published date: January 2008
Keywords: Bubbles, Drops, Gas-liquid flow, Potential flow, Two-phase flow, Viscous potential flow
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Identifiers

Local EPrints ID: 510677
URI: http://eprints.soton.ac.uk/id/eprint/510677
DOI: doi:10.1016/j.ijmultiphaseflow.2007.06.008
ISSN: 0301-9322
PURE UUID: 149f9d0d-4750-4d2a-a5bb-cfe46bdd3e62
ORCID for J.C. Padrino: ORCID iD orcid.org/0000-0002-6373-3469

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Date deposited: 16 Apr 2026 16:39
Last modified: 17 Apr 2026 02:11

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Contributors

Author: J.C. Padrino ORCID iD
Author: T. Funada
Author: D.D. Joseph

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