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 γ and the initial meniscus height hm. In the non-coalescence regime, the cavity evolves through inception, expansion, and rebound/jetting. The maximum cavity length hc follows a power-law scaling hcγα with α=-2.7 (experiments) and α=-2.6 (simulations) for 1.5γ3, where inertia dominates. Deviations emerge for γ1.5 (strong nonlinearity) and γ3 (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 hm plays only a secondary role relative to γ. 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 γ decreases. These findings are relevant to surface-jetting technologies, cavitation-erosion mitigation, and underwater-noise suppression.