Ultrasonic cavitation in CO2-expanded N, N-dimethylformamide (DMF)
•Ultrasonic cavitation is recorded by high-speed camera and hydrophone in a gas-expandedliquid system.•Content of CO2 has an important influence on evolution of bubble cloud.•Cavitation intensity depends on ultrasonic power and gas content.•The combination of ultrasound and gas-expanded liquid syste...
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Veröffentlicht in: | Ultrasonics sonochemistry 2021-10, Vol.78, p.105713-105713, Article 105713 |
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Sprache: | eng |
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Zusammenfassung: | •Ultrasonic cavitation is recorded by high-speed camera and hydrophone in a gas-expandedliquid system.•Content of CO2 has an important influence on evolution of bubble cloud.•Cavitation intensity depends on ultrasonic power and gas content.•The combination of ultrasound and gas-expanded liquid system greatly promotes mass transfer.
Due to the tunability in mass transfer, solvation and solubility, gas-expanded liquids show advantages over traditional organic solvents in many characteristics. Ultrasonication is a commonly used method to promote heat and mass transfer. The introduction of ultrasonic technology into the gas-expanded liquid system can promote the polymerization of polymer monomers, enhance extraction efficiency, and control the growth size of nanocrystals, etc. Although acoustic cavitation has been extensively explored in aqueous solutions, there are still few studies on cavitation in organic liquids, especially in gas-expanded liquid systems. In this article, the development of cavitation bubble cloud structure in CO2-expanded N, N-dimethylformamide (DMF) was observed by a high-speed camera, and the cavitation intensity was recorded using a spherical hydrophone. It was found that the magnitude of the transient cavitation energy was not only related to input power, but also closely related to CO2 content. The combination of ultrasound (causing a rapid alternation of gas solubility) and gas-expanded liquid system (causing a decrease in viscosity and surface tension of liquids) is expected to provide a perfect platform for high-speed mass transfer. |
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ISSN: | 1350-4177 1873-2828 |
DOI: | 10.1016/j.ultsonch.2021.105713 |