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LASER CAVITATION IN A TUBE IMMERSED IN A CONFINED VOLUME FILLED WITH LIQUID
- Authors: Guzev M.A1, Vassilevski Y.V2, Dats E.P1, Abushkin I.A1, Khaydukov E.V3, Chudnovskii V.M1
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Affiliations:
- Institute of Applied Mathematics Far Eastern Branch of the Russian Academy of Sciences
- G. I. Marchuk Institute of Computational Mathematics of the Russian Academy of Sciences
- National Research Center “Kurchatov Institute” of the Russian Academy of Sciences
- Issue: Vol 519, No 1 (2024)
- Pages: 19-25
- Section: ФИЗИКА
- URL: https://journals.rcsi.science/2686-7400/article/view/280115
- DOI: https://doi.org/10.31857/S2686740024060037
- EDN: https://elibrary.ru/HWLIIU
- ID: 280115
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Abstract
The expansion and collapse of a cavitation bubble during laser heating and boiling of water underheated to saturation temperature in the vicinity of the tip of an optical fiber (laser heating element) installed in a glass tube filled with water and immersed in a limited volume filled with liquid are studied. It is established that the outgoing and incoming flows of heated liquid in the tube, arising from the growth and collapse of cavitation vapor bubble, lead to intense horizontal liquid flows in the gap between the bottom of the cuvette and the bottom end of the tube. It is shown that at the initial moments of accelerated growth and, especially, at the moment of vapor bubble collapse near the bottom of the cuvette under the bottom end of the tube there are powerful pressure pulses that can effectively affect the surface of the bottom of the cuvette, while at bubble collapse liquid flows are directed in the opposite direction into the tube. The discovered effects can be used for effective selective surface cleaning.
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About the authors
M. A Guzev
Institute of Applied Mathematics Far Eastern Branch of the Russian Academy of SciencesAcademician of the RAS Vladivostok, Russia
Y. V Vassilevski
G. I. Marchuk Institute of Computational Mathematics of the Russian Academy of SciencesCorresponding Member of the RAS Moscow, Russia
E. P Dats
Institute of Applied Mathematics Far Eastern Branch of the Russian Academy of Sciences
Email: datsep@gmail.com
Vladivostok, Russia
I. A Abushkin
Institute of Applied Mathematics Far Eastern Branch of the Russian Academy of SciencesVladivostok, Russia
E. V Khaydukov
National Research Center “Kurchatov Institute” of the Russian Academy of SciencesMoscow, Russia
V. M Chudnovskii
Institute of Applied Mathematics Far Eastern Branch of the Russian Academy of SciencesVladivostok, Russia
References
- Рождественский В.В. Кавитация. Л.: Судостроение, 1977. 248 с.
- Chudnovskii V.M., Levin A.A., Yusupov V.I., Guzev M.A., Chernov A.A. The formation of a cumulative jet during the collapse of a vapor bubble in a subcooled liquid formed as a result of laser heating // Intern. J. Heat and Mass Transfer. 2020. N 150. P. 119286.
- Fursenko R.V., Chudnovskii V.M., Minaev S.S., Okajima J. Mechanism of high velocity jet formation after a gas bubble collapse near the micro fiber immersed in a liquid // International J. Heat and Mass Transfer. 2020. 163. 120420
- Zhong X., Eshraghi J., Vlachos P., Dabiri S., Ardekani A.M. A model for a laser-induced cavitation bubble // Intern. J. Multiphase Flow. 2020. V. 132. 103433. https://doi.org/10.1016/j.ijmultiphaseflow.2020.103433
- Ohl C.-D., Arora M., Dijkink R., Janve V., Lohse D. Surface cleaning from laser-induced cavitation bubbles // Appl. Phys. Lett. 2006. V. 89. 074102.
- Robles V., Gutierrez-Herrera E., Devia-Cruz L.F., Banks D., Camacho-Lopez S., Aguilar G. Soft material perforation via double-bubble laser-induced cavitation microjets // Phys. Fluids. 2020. V. 32. 042005. https://doi.org/10.1063/5.0007164
- George S.D., Chidangil S., Mathur D. Minireview: Laser-induced formation 0fmicrobubbles - biomedical implications // Langmuir. 2019. V. 35. 010139.
- Yu J.X., Wang X.Y., Hu J.S., Shen J.W., Zhang X.Q, Zheng X.X., Zhang Y.N., Yao Z. Laser-induced cavitation bubble near boundaries //j. Hydrodynamics. 2023. V. 35. P. 858-875. https://doi.org/10.1007/s42241-023-0074-3
- Wang D., Bi Y. Investigation of the influence of different liquid temperatures on the dynamics of longpulse laser-induced cavitation bubbles // AIP Advances. 2024. 14. https://doi.org/10.1063/5.0185608
- Horvat Darja, Orthaber Uroš, Schillec Jörg, Hartwigc Lars, Löschner Udo, Vrecko Andrej, Petkovšek Rok. Laser-induced bubble dynamics inside and near a gap between a rigid boundary and an elastic membrane // Intern. J. Multiphase Flow. 2018. V. 100. P. 119-126. https://doi.org/10.1016/j.ijmultiphaseflow.2017.12.010
- Schoppink J., Alvarez-Chavez J., Fernandez Rivas D. Laser beam properties and microfluidic confinement control thermocavitation // Appl. Phys. Letters. 2024. V. 124. https://doi.org/10.1063/5.0186998
- Чудновский В.М., Гузев М.А., Дац Е.П., Кулик А.В. Эффект ускоренного всасывания жидкости в трубке при лазерной кавитации на лазерном нагревательном элементе // Доклады РАН. Физика, технические науки. 2023. Т. 513. С. 41-47. https://doi.org/10.31857/s2686740023060056
- Dats E.P., Kulik A.V., Guzev M.A., Chudnovskii V.M. Cavitation at the end of an optical fiber during laser heating of water in a narrow slit // Technical Physics Letters. 2023. N 49. Р. 73-76.
- Чернов А.А., Гузев М.А., Пильник А.А., Адамова Т.П., Левин А.А., Чудновский В.М. Влияние вторичного вскипания на динамику струи, формирующейся при коллапсе парового пузырька, индуцированного лазерным нагревом жидкости // Доклады РАН. Физика, технические науки. 2021. Т. 501. С. 54-58.
- Wanga Shi-Ping, Wang Qianxi, Zhanga A-Man. Eleanor Stride. Experimental observations of the behaviour of a bubble inside a circular rigid tube // Intern. J. Multiphase Flow. 2019. V. 121. 103096. https://doi.org/10.1016/j.ijmultiphaseflow.2019.103096
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