An inverse method to fast-track the calculation of phase diagrams for sonoluminescing bubbles

•A efficient method is proposed to calculate the ambient radius and gas composition for sonoluminescing bubbles.•The method is based on diffusive equilibrium for each species inside the bubble.•On average, only ten acoustical cycles of dynamic simulation are needed.•The validation using existing exp...

Full description

Saved in:
Bibliographic Details
Published in:Ultrasonics sonochemistry 2021-05, Vol.73, p.105534-105534, Article 105534
Main Authors: Peng, Kewen, Qin, Frank G.F., Tian, Shouceng, Zhang, Yiqun
Format: Article
Language:English
Subjects:
Ambient radius and composition
Diffusive equilibrium
Inverse method
Short Communication
Sonoluminescing bubble
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•A efficient method is proposed to calculate the ambient radius and gas composition for sonoluminescing bubbles.•The method is based on diffusive equilibrium for each species inside the bubble.•On average, only ten acoustical cycles of dynamic simulation are needed.•The validation using existing experimental data shows the robustness of the method. A sound driven air bubble can be transformed into an argon bubble emitting light pulses stably. The very foundation to investigate the sonoluminescing bubble is to accurately determine the ambient radius and gas composition in the interior. The conventional approach is to model the air-to-argon transformation process through a large number of bubble dynamics simulations to obtain the physical parameters of the ultimate argon bubble. In this paper, we propose a highly efficient method to pinpoint this information in a phase diagram. The method is based on the diffusive equilibrium for each species inside the bubble and derives the ambient radius and composition inversely. To calculate the former parameter, the bisection algorithm is employed to consecutively narrow down the searching range until the equilibria is approached. Afterward, several cycles of full dynamics simulations are conducted to refine the composition. The method is validated using published experimental data. The calculated ambient radii deviate from the test results by less than 1 μm, which falls within the margin of measurement error. The advantages of this method over the semi-analytical approach reported by Hilgenfeldt et al. [J. Fluid Mech. 365 (1998)] are also discussed. Our study provides a standard procedure to calculate the ambient radius and composition and is beneficial for the numerical simulation of sonoluminescing bubbles.
ISSN:1350-4177
1873-2828
DOI:10.1016/j.ultsonch.2021.105534