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Finite amplitude wave propagation through bubbly fluids

Siew‐Wan Ohl, Juan Manuel Rosselló, Daniel Fuster, Claus‐Dieter Ohl

2024International Journal of Multiphase Flow13 citationsDOIOpen Access PDF

Abstract

The existence of only a few bubbles could drastically reduce the acoustic wave speed in a liquid. Wood’s equation models the linear sound speed, while the speed of an ideal shock waves is derived as a function of the pressure ratio across the shock. The common finite amplitude waves lie, however, in between these limits. We show that in a bubbly medium, the high frequency components of finite amplitude waves are attenuated and dissipate quickly, but a low frequency part remains. This wave is then transmitted by the collapse of the bubbles and its speed decreases with increasing void fraction. We demonstrate that the linear and the shock wave regimes can be smoothly connected through a Mach number based on the collapse velocity of the bubbles.

Topics & Concepts

PhysicsShock waveMechanicsAmplitudeMach numberMach waveMoving shockSpeed of soundWave propagationAcousticsAcoustic waveClassical mechanicsOpticsUltrasound and Cavitation PhenomenaMethane Hydrates and Related PhenomenaPlanetary Science and Exploration
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