Supersonic jet dynamics from two-cavitation-bubble interactions: acceleration, tip fragmentation and penetration

TL;DR

This paper explores the complex dynamics of high-speed liquid jets generated by interactions of two cavitation bubbles, revealing distinct jet regimes, underlying mechanisms, and potential biomedical applications.

Contribution

It provides the first detailed experimental and numerical analysis of two-bubble cavitation interactions and their influence on jet formation and penetration.

Findings

Identified three distinct jet regimes: conical, umbrella-shaped, and spraying.

Developed phase diagrams linking jet velocity and penetration to parameters.

Demonstrated spraying jets can penetrate over ten times the bubble radius.

Abstract

This study experimentally and numerically investigates the dynamics of a high-speed liquid jet generated from the interaction of two tandem cavitation bubbles, termed bubble 1 and bubble 2, depending on their generation sequence. In our experiments, two near-identical, highly-energized cavitation bubbles were generated using an underwater electric discharge method, and their transient interactions were captured using a high-speed camera. We identify three distinct jet regimes that emerge from the tip of bubble 2: conical, umbrella-shaped, and spraying jets, characterized by variations in the initial bubble-bubble distance and the initiation time difference. Our numerical simulations using both Volume of Fluid and Boundary Integral methods reproduce the experimental observations quite well and explain the mechanism of jet acceleration. We show that the transition between the regimes is governed by the spatiotemporal characteristics of the pressure wave induced by the collapse of bubble 1, which impacts the high-curvature tip of bubble 2. Specifically, a conical jet forms when the pressure wave impacts the bubble tip prior to its contraction, while an umbrella-shaped jet develops when this impact occurs after the contraction. The spraying jets result from the breakup of the bubble tip, exhibiting mist-like and needle-like morphologies with velocities ranging from 10 to over 1200 m/s. Remarkably, we observe that the penetration distance of spraying jets exceeds ten times the maximum bubble radius, making them ideal for long-range, controlled fluid delivery. Finally, phase diagrams for jet velocity and penetration distance in the $\gamma-\theta$ parameter space are established to provide a practical reference for biomedical applications, such as needle-free injection and micro-pumping.