The effects of nanoscale nuclei on cavitation

Under certain conditions, experimental values of the tensile strength of water are found to be much lower than theoretical values, even when the water is purified and degassed as much as possible. The discrepancy could be ascribed to stabilized nanobubbles or nanoparticles suspended in the liquid, a...

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Bibliographic Details
Published inJournal of fluid mechanics Vol. 911
Main Authors Gao, Zhan, Wu, Wangxia, Wang, Bing
Format Journal Article
LanguageEnglish
Published Cambridge, UK Cambridge University Press 25.01.2021
Subjects
Cavitation
Contaminants
Dynamics
Experiments
Gases
JFM Papers
Liquids
Mathematical models
Molecular dynamics
Nanoparticles
Nucleation
Nuclei
Nucleus
Simulation
Tensile strength
Water purification
cavitation
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Summary:Under certain conditions, experimental values of the tensile strength of water are found to be much lower than theoretical values, even when the water is purified and degassed as much as possible. The discrepancy could be ascribed to stabilized nanobubbles or nanoparticles suspended in the liquid, as such contaminants cannot be eliminated completely from a substantial liquid volume. Thus, the present study aims at elucidating the effects of such nanoscale nuclei on cavitation. A parameter-free mathematical model is derived to predict the cavitation arising from nanoscale nuclei, based on classical nucleation theory. To verify the model, molecular dynamics is used to simulate cavitation at nuclei of different sizes, embedded either in water or in liquid copper at different temperatures. The cavitation pressures calculated from the molecular dynamics results are compared with the predictions of the present mathematical model, with a good agreement between them. The results show that nanoscale nuclei significantly promote cavitation, i.e. the tensile strength is reduced notably by the presence of nanoscale nuclei. The tensile strength decreases when the size of nuclei increases, and the change rule of cavitation pressure is also affected by the liquid properties, such as liquid temperature. The present study may provide an acceptable explanation of the discrepancy between theory and experiment on the cavitation pressure in liquids purified and degassed as much as possible.
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ISSN:0022-1120
1469-7645
DOI:10.1017/jfm.2020.1049