Stroboscopic Schlieren Study of Bubble Formation during Megasonic Agitation

Marc Hauptmann; Steven Brems; Elisabeth Camerotto; Paul W. Mertens; Marc Heyns; Stefan de Gendt; Christ Glorieux; Walter Lauriks

doi:10.4028/www.scientific.net/SSP.187.185

Paper Titles

Simultaneous Removal of Particles from Front and Back Sides by a Single Wafer Backside Megasonic System
p.167

The Importance of Cavitation Hysteresis in Megasonic Cleaning
p.171

Control of Sonoluminescence in Carbon Dioxide Containing Di Water at near Neutral pH Conditions
p.177

Development of a Megasonic System for Cleaning Flat Panel Display
p.181

Stroboscopic Schlieren Study of Bubble Formation during Megasonic Agitation
p.185

Low-k Integration Using Metallic Hard Masks
p.193

Characterization of Low-k Dielectric Etch Residue on the Sidewall by Chemical Force Microscope
p.197

Optimized Wetting Behavior of Water-Based Cleaning Solutions for Plasma Etch Residue Removal by Application of Surfactants
p.201

Modification of Post-Etch Residues by UV for Wet Removal
p.207

HomeSolid State PhenomenaSolid State Phenomena Vol. 187Stroboscopic Schlieren Study of Bubble Formation...

Stroboscopic Schlieren Study of Bubble Formation during Megasonic Agitation

Abstract:

An important problem in megasonic cleaning is the nucleation process of bubbles, which act as the cleaning agents. A fundamental understanding of this nucleation process will help to optimize the cleaning parameters for future applications to achieve damage free cleaning. In this work, we use quantitative stroboscopic Schlieren imaging to study the interaction of nucleating bubbles with a travelling acoustic wave. The advantage of this method is that it is non-interfering, meaning that it does not disturb the bubble nucleation. It is revealed that nucleation mechanism is a 2 step process, where a regime of slow bubble growth due to rectified diffusion is subsequently followed by a transient cavitation cycle, where bubbles grow explosively. The latter is accompanied by broadband acoustic emission and enhanced thermal dissipation, leading to the occurrence of thermal convection visible in the Schlieren images.

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Periodical:

Solid State Phenomena (Volume 187)

Pages:

185-189

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.187.185

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Online since:

April 2012

Authors:

Marc Hauptmann, Steven Brems, Elisabeth Camerotto, Paul W. Mertens, Marc Heyns, Stefan de Gendt, Christ Glorieux, Walter Lauriks

Keywords:

Acoustic Cavitation, Bubble Nucleation, Megasonic Cleaning

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