# Cavitation erosion from single acoustically driven bubbles

**Authors:** Jaka Mur, Vid Agrež, Claus-Dieter Ohl, Rok Petkovšek

PMC · DOI: 10.1016/j.ultsonch.2026.107740 · 2026-01-07

## TL;DR

This study explores how a single acoustically driven bubble can cause erosion on solid surfaces, offering a controlled way to study cavitation effects.

## Contribution

The novel contribution is using a single, controlled acoustically driven bubble to systematically study and quantify cavitation erosion patterns.

## Key findings

- Erosion patterns on aluminum surfaces were measured after multiple bubble collapse events.
- Shockwave energy and position from bubble collapses were quantified using ultra-high-speed imaging and hydrophone sensors.
- Optical seeding enabled repeatable bubble behavior before transitioning into bubble clouds.

## Abstract

Acoustic cavitation is achieved by exciting mechanical vibrations at ultrasonic frequencies, which in turn cause the formation of bubble clouds, followed by flows and emulsification. Typically, the effects of acoustic cavitation clouds on cleaning and erosion are difficult to predict or model due to the complex interactions among numerous bubbles. Systematic studies of acoustic cavitation bubbles are simplified by using single cavitation bubbles as a means of controlled cavitation, owing to their precisely defined timing and properties, which can be induced within an acoustic field by seeding a small laser-induced bubble within it. This work presents findings on the erosion of solid surfaces initiated by a single acoustic bubble. Optical seeding of a small cavitation bubble is combined with acoustic driving under a sonotrode tip to generate a single, controlled, and isolated acoustically driven bubble oscillating near a solid boundary. The phase delay and spatial coordinates of optical seeding within the acoustic field are explored to achieve repeatable acoustic bubble behavior with multiple expansion–collapse cycles as a single bubble before transitioning into a bubble cloud composed of multiple smaller bubbles. Using an ultra-high-speed camera and a hydrophone pressure sensor, bubble collapses are quantified in terms of shockwave energy and position. Finally, the resulting erosion patterns on the aluminum surface are measured using confocal laser surface scanning after multiple event repetitions. This technique enables the study of erosion patterns produced by temporally and spatially confined acoustically driven bubbles.

## Full-text entities

- **Chemicals:** TiAl6V4 - 3.7165 (-), water (MESH:D014867), titanium (MESH:D014025), aluminium (MESH:D000535)

## Figures

5 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12828415/full.md

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Source: https://tomesphere.com/paper/PMC12828415