Investigation of the Low-Frequency Vibroacoustic Fields Influence on the Carbon Dioxide Absorption at the Liquid--Gas Phase Boundary

Abstrac

The work is a continuation of studying the influence of low-frequency acoustic axial low-energy vibrations of the infrasonic and early sound frequency ranges on the surface treatment rate of various structural materials, primarily those used in the radio electronics. Low-frequency vibration surface treatment of various alloys and semiconductors is one of the most promising modern tasks facing the domestic radio-electronic industry. Introduction of the low-frequency acoustic fields makes it possible to increase the rate in the metal surface treatment processes by 2--5 times. Currently, the so-called bubble etching method is widely used; it implies passing air bubbles through the etching solution during surface treatment. This allows intensifying the surface etching process and significantly increasing the rate (up to 3 times). Etching that uses the external acoustic field shows the similar results. Studies were performed to compare the process of gas dissolution in the field of low-frequency influences at the liquid-gas phase boundary and the process of bubbling the gas passing through distilled water. Experimental study results are presented explaining the reason for the etching processes acceleration in the low-frequency acoustic field due to the phenomenon of gas absorption at the phase boundary. A comparison of acoustic effects with bubbling and diffusion through the liquid-gas interface is provided

The work was funded by RFBR (project no. 20-33-90152) and the work was carried out according to the program of the State Assignment (no. FSFN-2023-0004)

Please cite this article in English as:

Boldyrev V.S., Bogatov N.A., Savina A.S., et al. Investigation of the low-frequency vibroacoustic fields influence on the carbon dioxide absorption at the liquid-gas phase boundary. Herald of the Bauman Moscow State Technical University, Series Natural Sciences, 2023, no. 6 (111), pp. 55--69 (in Russ.). DOI: https://doi.org/10.18698/1812-3368-2023-6-55-69

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