Cavitation-bubble Interaction with an Initially Perturbed Free Surface
Abstract
The interaction of a spark-generated cavitation bubble with an initially perturbed free surface is investigated experimentally, numerically, and analytically. By exploiting contact-line pinning, we accurately prescribe an initial meniscus with a thin, hydrophilic-coated rod inserted into the liquid. A pronounced surface cavity, driven by the oscillating bubble, forms and penetrates downward to a scale comparable to the bubble itself. The coupled cavity-bubble system exhibits two distinct regimes -- coalescence and non-coalescence -- separated by a critical condition governed by the non-dimensional stand-off parameter and the initial meniscus height . In the non-coalescence regime, the cavity evolves through inception, expansion, and rebound/jetting. The maximum cavity length follows a power-law scaling with (experiments) and (simulations) for , where inertia dominates. Deviations emerge for (strong nonlinearity) and (surface tension and viscosity become noticeable). An analytical model based on the Rayleigh-Plesset equation combined with nonlinear Rayleigh-Taylor instability theory captures the trend and confirms that plays only a secondary role relative to . In the coalescence regime, atmospheric air vents into the bubble through the merged cavity, weakening the collapse intensity and reducing the associated pressure peak. We also examine air/liquid compressibility and boundary layer effects, whose significance grows as decreases. These findings are relevant to surface-jetting technologies, cavitation-erosion mitigation, and underwater-noise suppression.
Cite
@article{arxiv.2604.04559,
title = {Cavitation-bubble Interaction with an Initially Perturbed Free Surface},
author = {Jingyu Gu and Zirui Liu and A-Man Zhang and Shuai Li},
journal= {arXiv preprint arXiv:2604.04559},
year = {2026}
}