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Temperature of a laser-induced cavitation jet generated at the tip of an optical fiber immersed in a liquid
Russian version
Dats E. P.1, Kulik A. V.1, Guzev M. A.1, Chudnovskii V. M.1
1Institute for Applied Mathematics, Far East Branch, Russian Academy of Sciences, Vladivostok, Russia
Email: datsep@gmail.com
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The temperature of a cavitation jet generated by laser cavitation at the end of an optical fiber immersed in water was studied experimentally and numerically. Laser heating and boiling of subcooled water are caused by continuous laser radiation with a wavelength of λ = 1.47 μm propagating along the optical fiber (thermal cavitation). It was shown that less than 4 % of the volume of the superheated liquid transforms into the vapor phase. The remaining superheated water, distributed over the surface of the vapor bubble, cools during its growth and collapse, and then transforms into a cavitation jet. The jet temperature during a single bubble growth and collapse event reaches 60 oC, which can be used in medical and technical applications. Keywords: cavitation jet, optical fiber, laser radiation.
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