Unified framework for laser-induced transient bubble dynamics within microchannels

Journal Article (2024)
Author(s)

Nagaraj Nagalingam (TU Delft - Complex Fluid Processing)

V.B. Korede (TU Delft - Complex Fluid Processing)

D. Irimia (TU Delft - Complex Fluid Processing)

J Westerweel (TU Delft - Fluid Mechanics)

Johan T. Padding (TU Delft - Complex Fluid Processing)

Remco Hartkamp (TU Delft - Complex Fluid Processing)

Huseyin Eral (TU Delft - Complex Fluid Processing)

Research Group
Complex Fluid Processing
DOI related publication
https://doi.org/10.1038/s41598-024-68971-x
More Info
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Publication Year
2024
Language
English
Related content
Research Group
Complex Fluid Processing
Issue number
1
Volume number
14
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Abstract

Oscillatory flow in confined spaces is central to understanding physiological flows and rational design of synthetic periodic-actuation based micromachines. Using theory and experiments on oscillating flows generated through a laser-induced cavitation bubble, we associate the dynamic bubble size (fluid velocity) and bubble lifetime to the laser energy supplied—a control parameter in experiments. Employing different channel cross-section shapes, sizes and lengths, we demonstrate the characteristic scales for velocity, time and energy to depend solely on the channel geometry. Contrary to the generally assumed absence of instability in low Reynolds number flows (<1000), we report a momentary flow distortion that originates due to the boundary layer separation near channel walls during flow deceleration. The emergence of distorted laminar states is characterized using two stages. First the conditions for the onset of instabilities is analyzed using the Reynolds number and Womersley number for oscillating flows. Second the growth and the ability of an instability to prevail is analyzed using the convective time scale of the flow. Our findings inform rational design of microsystems leveraging pulsatile flows via cavitation-powered microactuation.