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Auteurs principaux: J., Arun Krishna B., Tamadapu, Ganesh
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2502.00863
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author J., Arun Krishna B.
Tamadapu, Ganesh
author_facet J., Arun Krishna B.
Tamadapu, Ganesh
contents This paper presents a model for nonspherical oscillations of encapsulated bubbles coated with a polymer infused with magnetic particles, developed using membrane theory for thin weakly magnetic membranes. According to this theory, only the applied magnetic field significantly contributes to the Maxwell stress and membrane is under generalized plane stress. The study focuses on axisymmetric deformations of bubbles under symmetrically arranged magnetic coils. Non-spherical oscillations of the bubble are restricted to the linear regime, with the second mode dominating within the pressure range of the stability region. The pressure-frequency stability region is computationally determined, and its variation with different material properties and applied magnetic field is analyzed. The natural frequency of each mode is estimated using boundary layer approximation. Time-series analysis of the second mode amplitude reveals a significant oscillation amplitude relative to the bubble radius. Estimation using the model indicates that the interface magnetic susceptibility and initial bubble radius enhance the amplitude of second-mode oscillations. Computational findings suggest that the applied magnetic field does not influence the stability region for exponential stability.
format Preprint
id arxiv_https___arxiv_org_abs_2502_00863
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Nonspherical oscillations of an encapsulated magnetic microbubble
J., Arun Krishna B.
Tamadapu, Ganesh
Fluid Dynamics
This paper presents a model for nonspherical oscillations of encapsulated bubbles coated with a polymer infused with magnetic particles, developed using membrane theory for thin weakly magnetic membranes. According to this theory, only the applied magnetic field significantly contributes to the Maxwell stress and membrane is under generalized plane stress. The study focuses on axisymmetric deformations of bubbles under symmetrically arranged magnetic coils. Non-spherical oscillations of the bubble are restricted to the linear regime, with the second mode dominating within the pressure range of the stability region. The pressure-frequency stability region is computationally determined, and its variation with different material properties and applied magnetic field is analyzed. The natural frequency of each mode is estimated using boundary layer approximation. Time-series analysis of the second mode amplitude reveals a significant oscillation amplitude relative to the bubble radius. Estimation using the model indicates that the interface magnetic susceptibility and initial bubble radius enhance the amplitude of second-mode oscillations. Computational findings suggest that the applied magnetic field does not influence the stability region for exponential stability.
title Nonspherical oscillations of an encapsulated magnetic microbubble
topic Fluid Dynamics
url https://arxiv.org/abs/2502.00863