Issue 1, 2015

Gas bubble dynamics in soft materials

Abstract

Epstein and Plesset's seminal work on the rate of gas bubble dissolution and growth in a simple liquid is generalized to render it applicable to a gas bubble embedded in a soft elastic solid. Both the underlying diffusion equation and the expression for the gas bubble pressure were modified to allow for the non-zero shear modulus of the medium. The extension of the diffusion equation results in a trivial shift (by an additive constant) in the value of the diffusion coefficient, and does not change the form of the rate equations. But the use of a generalized Young–Laplace equation for the bubble pressure resulted in significant differences on the dynamics of bubble dissolution and growth, relative to an inviscid liquid medium. Depending on whether the salient parameters (solute concentration, initial bubble radius, surface tension, and shear modulus) lead to bubble growth or dissolution, the effect of allowing for a non-zero shear modulus in the generalized Young–Laplace equation is to speed up the rate of bubble growth, or to reduce the rate of bubble dissolution, respectively. The relation to previous work on visco-elastic materials is discussed, as is the connection of this work to the problem of Decompression Sickness (specifically, “the bends”). Examples of tissues to which our expressions can be applied are provided. Also, a new phenomenon is predicted whereby, for some parameter values, a bubble can be metastable and persist for long times, or it may grow, when embedded in a homogeneous under-saturated soft elastic medium.

Graphical abstract: Gas bubble dynamics in soft materials

Supplementary files

Article information

Article type
Paper
Submitted
10 Sep 2014
Accepted
03 Nov 2014
First published
03 Nov 2014

Soft Matter, 2015,11, 202-210

Author version available

Gas bubble dynamics in soft materials

J. M. Solano-Altamirano, J. D. Malcolm and S. Goldman, Soft Matter, 2015, 11, 202 DOI: 10.1039/C4SM02037E

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