
AbstractThe miniaturization boiling (micro-bubble emission boiling [MEB]) phenomenon, with a high heat removal capacity that contributes considerably to the cooling of the divertor of the nuclear fusion reactor, was discovered in the early 1980s. Extensive research on MEB has been performed since its discovery. However, the progress of the application has been delayed because the generation mechanism of MEB remains unclear. Reasons for this lack of clarity include the complexity of the phenomenon itself and the high-speed phase change phenomenon in which boiling and condensation are rapidly generated. In addition, a more advanced thermal technique is required to realize the MEB phenomenon at the laboratory scale. To the authors’ knowledge, few studies have discussed the rush mechanism of subcooled liquid to the heating surface, which is critical to elucidating the mechanism behind MEB. This study used photographic images to verify that the cavitation phenomenon spreads to the inside of the superheated liquid on the heating surface and thus clarify the mechanism of MEB.
Bubble, Subcooling, Physics, Materials Science, Superheating, Aerospace Engineering, FOS: Mechanical engineering, Mechanics, Article, Materials science, Nuclear Reactor Technology and Development, Engineering, Materials Challenges in Fusion Energy Research, Molecular Dynamics Simulations, Physical Sciences, Materials Chemistry, Boiling, Thermodynamics, Nuclear Thermal Hydraulics in Passive Systems
Bubble, Subcooling, Physics, Materials Science, Superheating, Aerospace Engineering, FOS: Mechanical engineering, Mechanics, Article, Materials science, Nuclear Reactor Technology and Development, Engineering, Materials Challenges in Fusion Energy Research, Molecular Dynamics Simulations, Physical Sciences, Materials Chemistry, Boiling, Thermodynamics, Nuclear Thermal Hydraulics in Passive Systems
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