Two-dimensional Rayleigh model for bubble evolution in soft tissue

The understanding of vapor bubble generation in a soft tissue near a fiber-optic tip has in the past required two-dimensional (2D) hydrodynamic simulations. For 1D spherical bubble expansions a simplified and useful Rayleigh-type model can be applied. For 2D bubble evolution, such a model has not be...

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Veröffentlicht in:	Physics of fluids (1994) 2002-05, Vol.14 (5), p.1768-1780
Hauptverfasser:	Friedman, Menahem, Strauss, Moshe, Amendt, Peter, London, Richard A., Glinsky, Michael E.
Format:	Artikel
Sprache:	eng
Schlagworte:	Boundary conditions Computer simulation Fiber optics Finite element method Hydrodynamics Mathematical models Problem solving Surface tension Viscosity
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container_end_page	1780
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container_title	Physics of fluids (1994)
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creator	Friedman, Menahem Strauss, Moshe Amendt, Peter London, Richard A. Glinsky, Michael E.
description	The understanding of vapor bubble generation in a soft tissue near a fiber-optic tip has in the past required two-dimensional (2D) hydrodynamic simulations. For 1D spherical bubble expansions a simplified and useful Rayleigh-type model can be applied. For 2D bubble evolution, such a model has not been developed. In this work we develop a Rayleigh-type model for 2D bubble expansion that is much faster and simpler than 2D hydrodynamic simulations and can be applied toward the design and understanding of fiber-based medical therapies. The model is based on a flow potential representation of the hydrodynamic motion and is described by a Laplace equation with a moving boundary condition at the bubble surface. In order for the Rayleigh-type 2D model to approximate bubble evolution in soft tissue, we include viscosity and surface tension in the fluid description. We show that the 1D Rayleigh equation is a special case of our model. The Laplace equation is solved for each time step by a finite-element solver using a fast triangular unstructured mesh generator. Our simulations include features of bubble evolution as seen in experiments and are in good agreement with 2D hydrodynamic simulations.
doi_str_mv	10.1063/1.1467654
format	Article
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For 1D spherical bubble expansions a simplified and useful Rayleigh-type model can be applied. For 2D bubble evolution, such a model has not been developed. In this work we develop a Rayleigh-type model for 2D bubble expansion that is much faster and simpler than 2D hydrodynamic simulations and can be applied toward the design and understanding of fiber-based medical therapies. The model is based on a flow potential representation of the hydrodynamic motion and is described by a Laplace equation with a moving boundary condition at the bubble surface. In order for the Rayleigh-type 2D model to approximate bubble evolution in soft tissue, we include viscosity and surface tension in the fluid description. We show that the 1D Rayleigh equation is a special case of our model. The Laplace equation is solved for each time step by a finite-element solver using a fast triangular unstructured mesh generator. 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subjects	Boundary conditions Computer simulation Fiber optics Finite element method Hydrodynamics Mathematical models Problem solving Surface tension Viscosity
title	Two-dimensional Rayleigh model for bubble evolution in soft tissue
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