Geodesic
Dependence of vapor compression in cavitation bubbles in water and benzol on liquid pressure
Učënye zapiski Kazanskogo universiteta. Seriâ Fiziko-matematičeskie nauki, Uchenye Zapiski Kazanskogo Universiteta. Seriya Fiziko-Matematicheskie Nauki, Tome 158 (2016) no. 2, pp. 231-242 Cet article a éte moissonné depuis la source Math-Net.Ru

Voir la notice du chapitre de livre

The features of strong vapor compression inside cavitation bubbles in benzol during their collapse have been studied depending on the liquid pressure in the range from 0.15 through 15 bar (the liquid temperature is $20^\circ$ C, the initial radius of the bubble is $500~\mu\mathrm m$). It has been found that three scenarios are implemented in this range of the liquid pressure: nearly homogeneous compression, compression by the radially converging simple waves, and compression by the radially converging shock waves. Shock waves are formed inside the bubble when the liquid pressure exceeds 0.25 bar. In contrast to benzol, there is only one possible scenario implemented in the case of cavitation bubble collapse in water under the same conditions, i.e., nearly homogeneous compression.
Mots-clés : acoustic cavitation, cumulation
Keywords: bubble dynamics, bubble collapse, converging shock waves. 
@article{UZKU_2016_158_2_a6,
     author = {A. A. Aganin and M. A. Ilgamov and D. Yu. Toporkov},
     title = {Dependence of vapor compression in cavitation bubbles in water and benzol on liquid pressure},
     journal = {U\v{c}\"enye zapiski Kazanskogo universiteta. Seri\^a Fiziko-matemati\v{c}eskie nauki},
     pages = {231--242},
     year = {2016},
     volume = {158},
     number = {2},
     language = {ru},
     url = {http://geodesic.mathdoc.fr/item/UZKU_2016_158_2_a6/}
}
TY  - JOUR
AU  - A. A. Aganin
AU  - M. A. Ilgamov
AU  - D. Yu. Toporkov
TI  - Dependence of vapor compression in cavitation bubbles in water and benzol on liquid pressure
JO  - Učënye zapiski Kazanskogo universiteta. Seriâ Fiziko-matematičeskie nauki
PY  - 2016
SP  - 231
EP  - 242
VL  - 158
IS  - 2
UR  - http://geodesic.mathdoc.fr/item/UZKU_2016_158_2_a6/
LA  - ru
ID  - UZKU_2016_158_2_a6
ER  - 
%0 Journal Article
%A A. A. Aganin
%A M. A. Ilgamov
%A D. Yu. Toporkov
%T Dependence of vapor compression in cavitation bubbles in water and benzol on liquid pressure
%J Učënye zapiski Kazanskogo universiteta. Seriâ Fiziko-matematičeskie nauki
%D 2016
%P 231-242
%V 158
%N 2
%U http://geodesic.mathdoc.fr/item/UZKU_2016_158_2_a6/
%G ru
%F UZKU_2016_158_2_a6
A. A. Aganin; M. A. Ilgamov; D. Yu. Toporkov. Dependence of vapor compression in cavitation bubbles in water and benzol on liquid pressure. Učënye zapiski Kazanskogo universiteta. Seriâ Fiziko-matematičeskie nauki, Uchenye Zapiski Kazanskogo Universiteta. Seriya Fiziko-Matematicheskie Nauki, Tome 158 (2016) no. 2, pp. 231-242. http://geodesic.mathdoc.fr/item/UZKU_2016_158_2_a6/

[1] Moss W. C., Clarke D. B., Young D. A., “Calculated pulse widths and spectra of a single sonoluminescing bubble”, Science, 276 (1997), 1398–1401 | DOI

[2] Nigmatulin R. I, Akhatov I. Sh., Topolnikov A. S., Bolotnova R. Kh., Vakhitova N. K., Lahey R. T. (Jr.), Taleyarkhan R. P., “The theory of supercompression of vapor bubbles and nano-scale thermonuclear fusion”, Phys. Fluids, 17:10 (2005), Art. 107106, 31 pp. | DOI

[3] Bass A., Ruuth S. J., Camara C., Merriman B., Putterman S., “Molecular dynamics of extreme mass segregation in a rapidly collapsing bubble”, Phys. Rev. Lett., 101:23 (2008), Art. 234301 | DOI

[4] Aganin A. A., Il'gamov M. A., Toporkov D. Yu., “Dependence of vapor compression inside cavitation bubbles in water and acetone on the pressure of liquid”, Vestn. Bashk. Univ., 20:3 (2015), 807–812 (In Russian)

[5] Putterman S. J., Weninger K. P., “Sonoluminescence: How bubbles turn sound into light”, Annu. Rev. Fluid Mech., 32 (2000), 445–476 | DOI | Zbl

[6] Galimov E. M., Kudin A. M., Skorobogatskii V. N., Plotnichenko V. G., Bondarev O. L., Zarubin B. G., Strazdovskii V. V., Aronin A. S., Fisenko A. V., Bykov I. V., Barinov A. Yu., “Experimental corroboration of the synthesis of diamond in the cavitation process”, Dokl. Phys., 49:3 (2004), 150–153 | DOI

[7] Voropaev S. A., Shkinev V. M., Dnestrovskii A. Yu., Ponomareva E. A., Aronin A. S., Bondarev O. L., Strazdovskii V. V., Skorobogatskii V. N., Eliseev A. A., Spivakov B. Ya., Galimov E. M., “Synthesis of diamondlike nanoparticles under cavitation in toluene”, Dokl. Phys., 57:10 (2012), 373–377 | DOI

[8] Voropaev S. A., Dnestrovskii A. Yu., Skorobogatskii V. N., Aronin A. S., Shkinev V. M., Bondarev O. L., Strazdovskii V. V., Eliseev A. A., Ponomareva E. A., Dushenko N. V., Galimov E. M., “Experimental study into the formation of nanodiamonds and fullerenes during cavitation in an ethanol-aniline mixture”, Dokl. Phys., 59:11 (2014), 503–506 | DOI | DOI

[9] Nigmatulin R. I., Dynamics of Multiphase Media, In 2 Parts, Nauka, Moscow, 1987 (In Russian)

[10] Nigmatulin R. I., Bolotnova R. Kh., “Wide-range equation of state of water and steam: simplified form”, High Temp., 49:2 (2011), 303–306 | DOI

[11] Bolotnova R. Kh., “Wide-range equation of state for organic liquids”, Tr. Inst. Mech. Ufim. Nauchn. Tsentra Ross. Akad. Nauk, 5, 2007, 113–120 (In Russian)

[12] Aganin A. A., “Dynamics of a small bubble in a compressible fluid”, Int. J. Numer. Meth. Fluids, 33:2 (2000), 157–174 | 3.0.CO;2-A class='badge bg-secondary rounded-pill ref-badge extid-badge'>DOI | Zbl

[13] Nigmatulin R. I., Aganin A. A., Toporkov D. Yu., Il'gamov M. A., “Formation of convergent shock waves in a bubble upon its collapse”, Dokl. Phys., 59:9 (2014), 431–435 | DOI | DOI | MR