Multibubble cavitation inception

TL;DR

This paper investigates how cavitation inception differs in multibubble systems compared to single bubbles, revealing suppression effects and the influence of bubble interactions on cavitation thresholds through numerical and theoretical analysis.

Contribution

It introduces a multibubble model incorporating acoustic interactions, demonstrating cavitation suppression phenomena and the impact of multiple bubbles on cavitation thresholds.

Findings

Large bubbles decrease cavitation threshold of small bubbles.

Suppression of cavitation can occur even under negative pressure.

More bubbles lead to stronger suppression effects.

Abstract

The inception of cavitation in multibubble cases is studied numerically and theoretically to show that it is different from that in single-bubble cases in several aspects. Using a multibubble model based on the Rayleigh-Plesset equation with an acoustic interaction term, we confirmed that the recently reported suppression of cavitation inception due to the interaction of non-identical bubbles can take place not only in liquid mercury but also in water, and we found that a relatively large bubble can significantly decrease the cavitation threshold pressure of a nearby small bubble. By examining in detail the transition region where the dynamics of the suppressed bubble changes drastically as the inter-bubble distance changes, we determined that the explosive expansion of a bubble under negative pressure can be interrupted and turn into collapse even though the far-field liquid pressure well exceeds the bubble's threshold pressure. Numerical results suggest that the interruption of expansion occurs when the bubble radius is exceeded by the instantaneous unstable equilibrium radius of the bubble determined using the total pressure acting on the bubble. When we extended the discussion to systems of larger numbers of bubbles, we found that a larger number of bubbles have a stronger suppression effect. The present findings would be useful in understanding the complex behavior of cavitation bubbles in practical applications where in general many cavitation nuclei exist and may interact with each other.