Litcius/Paper detail

Vapor compression and energy dissipation in a collapsing laser-induced bubble

Davide Bernardo Preso, Daniel Fuster, A. B. Sieber, Danail Obreschkow, Mohamed Farhat

2024Physics of Fluids28 citationsDOIOpen Access PDF

Abstract

The composition of the gaseous phase of cavitation bubbles and its role on the collapse remains to date poorly understood. In this work, experiments of single cavitation bubbles in aqueous ammonia serve as a novel approach to investigate the effect of the vapor contained in a bubble on its collapse. We find that the higher vapor pressure of more concentrated aqueous ammonia acts as a resistance to the collapse, reducing the total energy dissipation. In line with visual observation, acoustic measurements, and luminescence recordings, it is also observed that higher vapor pressures contribute to a more spherical collapse, likely hindering the growth of interface instabilities by decreasing the collapse velocities and accelerations. Remarkably, we evidence a strong difference between the effective damping and the energy of the shock emission, suggesting that the latter is not the dominant dissipation mechanism at collapse as predicted from classical correction models accounting for slightly compressible liquids. Furthermore, our results suggest that the vapor inside collapsing bubbles gets compressed, consistently with previous studies performed in the context of single bubble sonoluminescence, addressing the question about the ability of vapors to readily condense during a bubble collapse in similar regimes. These findings provide insight into the identification of the influence of the bubble content and the energy exchanges of the bubble with its surrounding media, eventually paving the way to a more efficient use of cavitation in engineering and biomedical applications.

Topics & Concepts

SonoluminescenceBubbleCavitationPhysicsDissipationMechanicsShock waveContext (archaeology)Shock (circulatory)CompressibilityThermodynamicsInternal medicineBiologyMedicinePaleontologyUltrasound and Cavitation PhenomenaAnesthesia and Neurotoxicity ResearchUltrasound and Hyperthermia Applications