High temperature and pressure inside a dissolving oxygen nanobubble

•Numerical simulations are performed for dissolution of an oxygen nanobubble.•A few molecules of OH radicals may be formed per 107 dissolving oxygen nanobubbles.•The production rate is 13 orders of magnitude smaller than the experimental data.•In a dissolving oxygen nanobubble, 2800 K and 4.5 GPa ar...

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Bibliographic Details
Published in:Ultrasonics sonochemistry 2019-07, Vol.55, p.308-312
Main Authors: Yasui, Kyuichi, Tuziuti, Toru, Kanematsu, Wataru
Format: Article
Language:English
Subjects:
Bubble dissolution into water
Numerical simulation
OH radical
Oxygen (O2) bubble
Without dynamic stimuli
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Summary:•Numerical simulations are performed for dissolution of an oxygen nanobubble.•A few molecules of OH radicals may be formed per 107 dissolving oxygen nanobubbles.•The production rate is 13 orders of magnitude smaller than the experimental data.•In a dissolving oxygen nanobubble, 2800 K and 4.5 GPa are achieved. Numerical simulations of dissolution of an oxygen (O2) nanobubble into water without dynamic stimuli have been performed in order to study the possibility of OH radical formation from oxygen nanobubbles experimentally reported by Liu et al. (2016). The dissolution of an oxygen nanobubble is much faster than that of an air nanobubble due to higher solubility of oxygen in water. However, the temperature and pressure inside an oxygen nanobubble at the final moment of the bubble dissolution are about 2800 K and 4.5 GPa, respectively, which are slightly lower than those inside an air nanobubble due to higher thermal conductivity of oxygen. A few molecules of OH radicals may be formed per 107 bubbles according to the numerical simulation. The estimated production rate of OH radicals is 13 orders of magnitude smaller than the experimentally reported one.
ISSN:1350-4177
1873-2828
DOI:10.1016/j.ultsonch.2019.01.013