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Related Experiment Video

Updated: Jul 9, 2025

Induction of Microstreaming by Nonspherical Bubble Oscillations in an Acoustic Levitation System
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A method for consistent cavitation bubble generation at different voltages.

Akurati Prabhakar1, Urbesh Sarkar2, Ritwik Ghoshal1

  • 1Department of Ocean Engineering and Naval Architecture, Indian Institute of Technology Kharagpur, Kharagpur, India.

The Review of Scientific Instruments
|December 8, 2023
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Summary
This summary is machine-generated.

Researchers enhanced an underwater electrical discharge circuit to precisely control cavitation bubble dynamics. This improved system allows for adjustable bubble sizes up to 14mm, crucial for understanding fluid dynamics and material processing applications.

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Area of Science:

  • Fluid Dynamics
  • Plasma Physics
  • Acoustics

Background:

  • Cavitation bubble dynamics are critical for numerous scientific and engineering applications.
  • Underwater electrical discharge is a common method for generating and studying these bubbles.
  • Existing methods have limitations in controlling bubble size and experimental repeatability.

Purpose of the Study:

  • To improve an underwater low-voltage discharge circuit for generating cavitation bubbles.
  • To achieve a wider range of maximum bubble radii and enhance experimental repeatability.
  • To investigate the relationship between delivered energy, bubble potential energy, and bubble dynamics.

Main Methods:

  • A novel electric circuit design with variable voltage (up to 420V) using relay-controlled capacitor networks.
  • Integration of a voltage sensor to measure discharge voltage drop.
  • Utilizing a semiconductor field-effect transistor for consistent bubble generation.
  • Employing a high-speed imaging system to measure bubble radius and nucleation period.

Main Results:

  • The improved circuit generates oscillating cavitation bubbles up to a maximum radius of 14mm.
  • A correlation between delivered energy and bubble potential energy was established.
  • Dependence of bubble radius on circuit resistance, electrode resistance, and material was analyzed.
  • Electrode oxidation delay was found to influence bubble collapse and internal pressure.

Conclusions:

  • The novel circuit design offers enhanced control over cavitation bubble generation and size.
  • Experimental repeatability is significantly improved through precise control of discharge energy.
  • Understanding electrode material properties and oxidation is key to optimizing bubble collapse dynamics.