Rebounds of deformed cavitation bubbles

Supponen, Outi; Obreschkow, Danail; Farhat, Mohamed

doi:10.1103/physrevfluids.3.103604

Cited by 45 publications

(23 citation statements)

References 51 publications

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“…We provide here a selection of the most important results obtained with the experimental setup explained above. Interested readers may refer to the more indepth publications by the Flash and Splash team [11][12][13][14][15][16][17][18][19][20][21][22][23][24][25].…”

Section: Major Resultsmentioning

confidence: 99%

“…I did not know that this meeting of September 2004 was the start of a long and fruitful research activity on bubble dynamics in microgravity, which continues today. Following the first participation in the students flight campaign, we took part in eight research campaigns with the involvement of four PhD students, M. Tinguely [2], O. Supponen [3], A. Sieber and D. Preso with many other master students and technicians. This innovative and exciting research, which received financial supports from the Swiss National Science Foundation, the European Union and many other governmental and private institutions, produced a strong impact within the scientific community and beyond.…”

Section: Introductionmentioning

confidence: 99%

“…Top: visualization of a laser-induced bubble dynamics (112 μs inter-frame); middle: measured bubble radius (blue circles), along with theoretical predictions; bottom: pressure signal measured far from the bubble centre (reproduced from[3]). …”

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confidence: 99%

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What We Learned from Cavitation Bubbles in Microgravity

Farhat¹

2020

Preparation of Space Experiments

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The present chapter is about the Flash and Splash project, which is dedicated to the study of bubble dynamics in microgravity. The story of this project started in 2004 with a simple curiosity on how a cavitation bubble may behave within a water drop and evolved into an outstanding, internationally renowned science project as well as a wonderful human adventure. So far, we have participated in nine European Space Agency (ESA) parabolic flight campaigns (PFC) and made a significant progress in understanding the cavitation phenomenon. First, we investigated the dynamics of a cavitation bubble within a water drop and learned how the collapse may lead to the formation of a double jet. We discovered the formation of secondary cavitation due to the confinement of shockwaves within the drop. We used this result to propose a new path for erosion due to a high-speed impact of water drops on a solid surface. Then, we addressed the effect of gravity on bubble dynamics and came up with a unified framework to explain and predict key phenomena, such as microjets, shockwaves and luminescence. Parabolic flights gave us the unique opportunity to modulate the gravity-induced pressure gradient, which is crucial for the fate of a collapsing bubble.

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Section: Major Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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What We Learned from Cavitation Bubbles in Microgravity

Farhat¹

2020

Preparation of Space Experiments

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“…When the collapse of a bubble occurs near a structure, the structure will bear an impact due to the collapsing bubble [3]. At the same time, high-speed liquid jets can also occur in the final stage of bubble collapse [4,5]. erefore, the damage characteristics of bubbles to adjacent structures are critical in fluid mechanics.…”

Section: Introductionmentioning

confidence: 99%

A New Measurement Based on HPB to Measure the Wall Pressure of Electric-Spark-Generated Bubble near the Hemispheric Boundary

Shi

Cui

et al. 2020

Shock and Vibration

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Direct measurement of the wall pressure loading of the spherical boundary subjected to the near-field underwater explosion is a great difficulty. To investigate the wall pressure caused by electric-spark-generated bubble near a hemispheric boundary, an experiment system is developed. In the method of this experiment, a Hopkinson bar (HPB), used as the sensing element, is inserted through the hole drilled on the hemisphere target and the bar’s measuring end face lies flush with the loaded face of the hemisphere target to detect and record the pressure loading. The semiconductor strain gauges which stick on Hopkinson bar are used to convert the pressure-based signal to the strain wave signal. The bubble in the experiments is formed by a discharge of 400 V high voltage. To validate the pressure measurement technique based on the HPB, an experimental result from pressure transducer is used as the validating system. To verify the capability of this new methodology and experimental system, a series of electric-spark-generated bubble experiments are conducted. From the recorded pressure-time profiles coupled with the underwater explosion evolution images captured by the high-speed camera (HSV), the shock wave pressure loading and bubble collapse pressure loadings are captured in detail at different dimensionless stand-off distances γ from 0.17 to 2.00. From the results of the experiments conducted in this paper, the proposed experiment system can be used to measure the pressure signal successfully, giving new way to study the bubble collapse pressure when the bubble is near a hemispheric boundary. Through the experimental results, the bubbles generated by different dimensionless stand-off distance γ are divided into four categories, and the bubble load characteristics are also discussed.

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“…Indications that the refocused shock waves may play an important role in laser-induced, breakdown-based medical procedures in human eyes are scattered over the literature. It is well known that when laser breakdown is generated in water close to its free surface, smaller secondary bubbles appear within the laser path after the shock wave reflected from the free surface overpasses the volume irradiated by the laser pulse [18,19]. Additional focusing of shock waves from concave surfaces, such as from the internal walls of round flasks [20], rising free water surfaces [21], free surfaces of liquid jets [22] and water drops [23] make the secondary cavitation even more pronounced.…”

Section: Introductionmentioning

confidence: 99%

Cavitation induced by shock wave focusing in eye-like experimental configurations

Požar

Petkovšek

2019

Biomed. Opt. Express

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During laser-induced, breakdown-based medical procedures in human eyes such as posterior capsulotomy and vitreolysis, shock waves are emitted from the location of the plasma. A part of these spherically expanding transients is reflected from the concave surface of the corneal epithelium and refocused within the eye. Using a simplified experimental model of the eye, the dominant secondary cavitation clusters were detected by high-speed camera shadowgraphy in the refocusing volume, dislocated from the breakdown position and described by an abridged ray theory. Individual microbubbles were detected in the preheated cone of the incoming laser pulse and radially extending cavitation filaments were generated around the location of the breakdown soon after collapse of the initial bubble. The generation of the secondary cavitation structures due to shock wave focusing can be considered an adverse effect, important in ophthalmology.

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Rebounds of deformed cavitation bubbles

Cited by 45 publications

References 51 publications

What We Learned from Cavitation Bubbles in Microgravity

What We Learned from Cavitation Bubbles in Microgravity

A New Measurement Based on HPB to Measure the Wall Pressure of Electric-Spark-Generated Bubble near the Hemispheric Boundary

Cavitation induced by shock wave focusing in eye-like experimental configurations

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