Geodesic
Numerical modeling of the evolution of a vapor bubble under conditions of laser-induced cavitation
Dalʹnevostočnyj matematičeskij žurnal, Tome 23 (2023) no. 2, pp. 178-183.

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Based on the Lee vaporization-condensation model, numerical solutions were obtained that describe the process of growth and collapse of bubbles formed at the end of an optical fiber during laser heating. The simulation parameters are found for which the numerical solutions correspond to the observed experimental data. Using numerical modeling, the features associated with the dynamics of the growth-collapse of a cavitation bubble and the formation of heated jets are explained 
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     title = {Numerical modeling of the evolution of a vapor bubble under conditions of laser-induced cavitation},
     journal = {Dalʹnevosto\v{c}nyj matemati\v{c}eskij \v{z}urnal},
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M. A. Guzev; E. P. Dats; Yu. P. Pahkalyuk; V. M. Chudnovskii. Numerical modeling of the evolution of a vapor bubble under conditions of laser-induced cavitation. Dalʹnevostočnyj matematičeskij žurnal, Tome 23 (2023) no. 2, pp. 178-183. http://geodesic.mathdoc.fr/item/DVMG_2023_23_2_a3/

[1] R. V. Fursenko, V. M. Chudnovskii, S. S. Minaev, Dzh. Okadzima, “Mechanism of high velocity jet formation after a gas bubble collapse near the micro fiber immersed in a liquid”, International Journal of Heat and Mass Transfer, 163 (2020), 120420 | DOI

[2] A. V. Kulik, S. N. Mokrin, A. M. Kraevskii, S. S. Minaev, M. A. Guzev, V. M. Chudnovskii, “Features of dynamics of a jet flow generated on a laser heater by surface boiling of liquid”, Technical Physics Letters, 48 (2022), 60–63 | DOI

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