Cleaning effects due to shape oscillation of bubbles over a rigid boundary

Author:

Corbett Callan1ORCID,Wang QianxiORCID,Smith Warren1ORCID,Liu WenkeORCID,Walmsley A. Damien2ORCID

Affiliation:

1. School of Mathematics, University of Birmingham 1 , Edgbaston, Birmingham B15 2TT, United Kingdom

2. School of Dentistry, College of Medical and Dental Sciences, University of Birmingham 3 , 5 Mill Pool Way, Birmingham B5 7EG, United Kingdom

Abstract

Recent experiments have revealed the interesting cleaning effects that take place due to the shape mode oscillation of bubbles over a rigid boundary. While a microbubble was undertaking shape oscillation moving over a bacterial biofilm, it removed the contaminants from the boundary and created a clean path through the biofilm. This demonstrated much higher cleaning efficiency than that associated with the volume oscillation of cavitation bubbles; however, the mechanism is unknown. Here, we study this phenomenon using the boundary integral method with the viscous effects modeled using the viscous potential flow theory and the compressible effects using the weakly compressible theory. The viscous stress at the rigid boundary is approximated using the boundary layer theory. We observed that the natural frequencies of shape mode oscillation decrease significantly due to the presence of the boundary. The shear stress at the boundary due to the shape oscillation of a nearby bubble is at least 20 times higher than that due to volume oscillation with the same energy and is significant only within the area directly beneath the bubble. This is explained by the notably faster decay for higher shape modes of the kinetic energy in the fluid as the distance to the center of the bubble r increases with the induced velocity of mode k decaying at a rate of O(r−(k+2)) away from the bubble. These results achieve excellent agreement with the intriguing cleaning effects first observed in the experiment and explain the mechanism behind this new highly efficient method of cleaning.

Funder

Engineering and Physical Sciences Research Council

Publisher

AIP Publishing

Subject

Condensed Matter Physics,Fluid Flow and Transfer Processes,Mechanics of Materials,Computational Mechanics,Mechanical Engineering

Reference38 articles.

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