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Based on the perturbation theory and generalized Bernoulli equation, the equations describing the radius, translation and deformation of a single gas bubble in ultrasonic field are derived. The evolutions of the radius, displacement and deformation of the bubble with time can be obtained by numerically calculating these equations. The calculation results show that when the initial radius of the bubble and the driving pressure both keep constant, the displacement and shape variable of the bubble increase with the augment of the initial translational velocity of the bubble’s center, and the non-spherical vibration of the bubble becomes more intense. However, the radial vibration of the bubble almost remains unchanged. When the initial translation velocity of the bubble is relatively small, the unstable region is concentrated only in the region of high driving sound pressure in the
$R_{0}\text-p_{\rm a}$ phase diagram of the bubble. As the initial translational velocity increases, the region with small radius and driving sound pressure begins to show instability, and the overall unstable region gradually increases. In addition, a bubble presents different vibration characteristics at different positions in the acoustic standing wave field. The closer to the antinode of sound wave the bubble is, the greater the radial amplitude of the bubble’s vibration is. However, the variable of the translation and shape of the bubble are very small. The error between the plane fractions of the unstable region in the phase diagram of$R_{0}\text{-} p_ {\rm a}$ is less than 4%.-
Keywords:
- caviation bubble /
- translation /
- non-spherical oscillation /
- instability
[1] Leighton T G 1977 The Acoustic Bubble (San Diego: Academic Press) p72
[2] Frenzel H, Schultes H 1934 Z. Phys. Chem. Abt. B 27 421Google Scholar
[3] Niemczewski B 2014 Ultrason. Sonochem. 21 354Google Scholar
[4] Oshima R, Yamamoto T A, Mizukoshi Y, Nagata Y, Maeda Y 1999 Nanostruct. Mater. 12 111Google Scholar
[5] Hussein E M, Khairou K S 2014 Rev. J. Chem. 4 221Google Scholar
[6] Rayleigh L 1917 Philos. Mag. 34 94Google Scholar
[7] Plesset M S 1954 J. Appl. Phys. 25 96Google Scholar
[8] Keller J B, Miksis M 1980 J. Acoust. Soc. Am. 68 628Google Scholar
[9] Hilgenfeldt S, Lohse D, Brenner M P 1996 Phys. Fluids 8 2808Google Scholar
[10] An Y, Lu T, Yang B 2005 Phys. Rev. E 71 026310Google Scholar
[11] Zhang W J, An Y 2013 Phys. Rev. E 87 053023Google Scholar
[12] Liang J F, Chen W Z, Shao W H, Qi S B 2012 Chin. Phys. Lett. 29 074701Google Scholar
[13] Liang J F, Wang X, Yang J, Gong L X 2017 Ultrasonics 75 58Google Scholar
[14] Madrazo A, García N, Nieto-Vesperinas M 1998 Phys. Rev. Lett. 80 4590Google Scholar
[15] Barbat T, Ashgriz N, Liu C S 1999 J. Fluid Mech. 389 137Google Scholar
[16] Flannigan D J, Suslick K S 2007 Phys. Rev. Lett. 99 134301Google Scholar
[17] Cui W C, Chen W Z, Qi S B, Zhou C, Tu J 2012 J. Acoust. Soc. Am. 132 138Google Scholar
[18] Wu W H, Yang P F, Zhai W, Wei B B 2019 Chin. Phys. Lett. 36 084302Google Scholar
[19] Wu W H, Eskin D G, Priyadarshi A, Subroto T, Tzanakis I, Zhai W 2021 Ultrason. Sonochem. 73 105501Google Scholar
[20] Doinikov A A 2001 Phys. Rev. E 64 026301Google Scholar
[21] Doinikov A A 2002 Phys. Fluids 14 1420Google Scholar
[22] 沈壮 志 2015 物理学报 64 124702Google Scholar
Shen Z Z 2015 Acta Phys. Sin. 64 124702Google Scholar
[23] 马艳, 林书玉, 徐洁 2018 物理学报 67 034301Google Scholar
Ma Y, Lin S Y, Xu J 2018 Acta Phys. Sin. 67 034301Google Scholar
[24] Zhang L L, Chen W Z, Zhang Y Y, Wu Y R, Wang X, Zhao G Y 2020 Chin. Phys. B 29 034303Google Scholar
[25] Feng Z C, Leal L G 1995 Phys. Fluids 7 1325Google Scholar
[26] Reddy A J, Szeri A J 2002 Phys. Fluids 14 2216Google Scholar
[27] Doinikov A A 2004 J. Fluid Mech. 501 1Google Scholar
[28] Mettin R, Doinikov A A 2009 Appl. Acoust. 70 1330Google Scholar
[29] 刘式适, 刘式达 2002 特殊函数 (第二版) (北京: 气象出版社) 第255, 237−240, 247−251页
Liu S S, Liu S D 2002 Special Function (2nd Ed.) (Beijing: Qixiang Press) pp255, 237−240, 247−251 (in Chinese)
[30] Franc J P, Michel J M 2004 Fundamentals of Cavitation (Nether- lands: Kluwer Academic Publisher) p341
[31] Plesset M S 1949 J. Appl. Mech. 16 277Google Scholar
[32] 陈伟中 2014 声空化物理 (北京: 科学出版社) 第250−253页
Chen W Z 2014 Physics of Acoustic Cavitation (Beijing: Science Press) pp250−253 (in Chinese)
[33] Tsiglifis K, Pelekasi N A 2005 Phys. Fluids 17 102101Google Scholar
[34] Kostas T, Pelekasis N A 2007 Ultrason. Sonochem. 14 456Google Scholar
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图 2 不同初始平移速度
$v_{x0}$ 下, (a)气泡径向半径、(b)气泡中心平移以及(c)气泡表面形变随时间的演化.$R_{0}$ = 4.5 µm,$p_{\rm a}$ = 1.15 × 105 PaFigure 2. Evolutions of (a) radius, (b) translation and (c) deformation with time for a cavitation bubble with different initial translational velocity (
$v_{x0}$ ), respectively.$R_{0}$ = 4.5 µm,$p_{\rm a}$ = 1.15 × 105 Pa图 3 不同初始平移速度条件下, 不同时刻气泡振动的形状 (a)
$v_{x0}$ = 0; (b)$v_{x0}$ = 1 m/s; (c)$v_{x0}$ = 3 m/s; (d)$v_{x0}$ = 5 m/s. 其中$R_{0}$ = 4.5 µm,$p_{\rm a}$ = 1.15 × 105 PaFigure 3. Simulations of shapes of a gas bubble’s oscillation at different times under different initial translational velocity: (a)
$v_{x0}$ = 0; (b)$v_{x0}$ = 1 m/s; (c)$v_{x0}$ = 3 m/s; (d)$v_{x0}$ = 5 m/s.$R_{0}$ = 4.5 µm,$p_{\rm a}$ = 1.15 × 105 Pa图 4 不同初始平移速度下, 气泡的
${R_{0}}\text {-}$ $p_{\rm a}$ 相图 (a)$v_{x0}$ = 0; (b)$v_{x0}$ = 1 m/s; (c)$v_{x0}$ = 3 m/s; (d)$v_{x0}$ = 5 m/s.$p_{\rm a}= $ $ 1.15$ × 105 Pa,$R_{0}$ = 4.5 µmFigure 4.
${R_{0}}\text {-}$ $p_{\rm a}$ phase diagram of a gas bubble under different initial translational velocity: (a)$v_{x0}$ = 0; (b)$v_{x0}$ = 1 m/s; (c)$v_{x0}$ = 3 m/s; (d)$v_{x0}$ = 5 m/s.$p_{\rm a}=1.15$ × 105 Pa,$R_{0}$ = 4.5 µm图 6 不同位置处, 不同时刻气泡振动的形状(
$p_{\rm a}=1.15$ × 105 Pa,$R_{0}$ = 4.5 µm,$v_{x0}$ = 5 m/s) (a) d = 0; (b) d = λ/5; (c) d = λ/4; (d) d = λ/2Figure 6. Simulations of shapes of a gas bubble’s oscillation at different times at different distances from the antinodal of acoustical wave: (a) d = 0; (b) d = λ/5; (c) d = λ/4; (d) d = λ/2.
$p_{\rm a}=1.15$ × 105 Pa,$R_{0}$ = 4.5 µm,$v_{x0}$ = 5 m/s.图 7 不同位置处, 气泡的
$R_{0}$ -$p_{\rm a}$ 相图($p_{\rm a}=1.15$ × 105 Pa,$R_{0}$ = 4.5 µm,$v_{x0}$ = 5 m/s) (a) d = 0; (b) d = λ/5; (c) d = λ/4; (d) d = λ/2Figure 7.
$R_{0}$ -$p_{\rm a}$ phase diagrams of a gas bubble at different distances from the antinodal of acoustical wave: (a) d = 0; (b) d = λ/5; (c) d = λ/4; (d) d = λ/2.$p_{\rm a}=1.15$ × 105 Pa,$R_{0}$ = 4.5 µm,$v_{x0}$ = 5 m/s.表 1 数值计算中使用的物理量参数
Table 1. Physical parameters used in the numerical calculation.
物理量 单位 数值 液体密度ρ kg/m3 1000 液体中声速c m/s 1481 液体表面张力系数σ N/m 0.072 液体粘度系数η Pa·s 0.001 超声频率f Hz 2.5 × 104 气泡内初始压强$ p_{0}$ Pa 1.013 × 105 环境压强$ p_{\infty}$ Pa 1.013 × 105 绝热指数γ 1.4 -
[1] Leighton T G 1977 The Acoustic Bubble (San Diego: Academic Press) p72
[2] Frenzel H, Schultes H 1934 Z. Phys. Chem. Abt. B 27 421Google Scholar
[3] Niemczewski B 2014 Ultrason. Sonochem. 21 354Google Scholar
[4] Oshima R, Yamamoto T A, Mizukoshi Y, Nagata Y, Maeda Y 1999 Nanostruct. Mater. 12 111Google Scholar
[5] Hussein E M, Khairou K S 2014 Rev. J. Chem. 4 221Google Scholar
[6] Rayleigh L 1917 Philos. Mag. 34 94Google Scholar
[7] Plesset M S 1954 J. Appl. Phys. 25 96Google Scholar
[8] Keller J B, Miksis M 1980 J. Acoust. Soc. Am. 68 628Google Scholar
[9] Hilgenfeldt S, Lohse D, Brenner M P 1996 Phys. Fluids 8 2808Google Scholar
[10] An Y, Lu T, Yang B 2005 Phys. Rev. E 71 026310Google Scholar
[11] Zhang W J, An Y 2013 Phys. Rev. E 87 053023Google Scholar
[12] Liang J F, Chen W Z, Shao W H, Qi S B 2012 Chin. Phys. Lett. 29 074701Google Scholar
[13] Liang J F, Wang X, Yang J, Gong L X 2017 Ultrasonics 75 58Google Scholar
[14] Madrazo A, García N, Nieto-Vesperinas M 1998 Phys. Rev. Lett. 80 4590Google Scholar
[15] Barbat T, Ashgriz N, Liu C S 1999 J. Fluid Mech. 389 137Google Scholar
[16] Flannigan D J, Suslick K S 2007 Phys. Rev. Lett. 99 134301Google Scholar
[17] Cui W C, Chen W Z, Qi S B, Zhou C, Tu J 2012 J. Acoust. Soc. Am. 132 138Google Scholar
[18] Wu W H, Yang P F, Zhai W, Wei B B 2019 Chin. Phys. Lett. 36 084302Google Scholar
[19] Wu W H, Eskin D G, Priyadarshi A, Subroto T, Tzanakis I, Zhai W 2021 Ultrason. Sonochem. 73 105501Google Scholar
[20] Doinikov A A 2001 Phys. Rev. E 64 026301Google Scholar
[21] Doinikov A A 2002 Phys. Fluids 14 1420Google Scholar
[22] 沈壮 志 2015 物理学报 64 124702Google Scholar
Shen Z Z 2015 Acta Phys. Sin. 64 124702Google Scholar
[23] 马艳, 林书玉, 徐洁 2018 物理学报 67 034301Google Scholar
Ma Y, Lin S Y, Xu J 2018 Acta Phys. Sin. 67 034301Google Scholar
[24] Zhang L L, Chen W Z, Zhang Y Y, Wu Y R, Wang X, Zhao G Y 2020 Chin. Phys. B 29 034303Google Scholar
[25] Feng Z C, Leal L G 1995 Phys. Fluids 7 1325Google Scholar
[26] Reddy A J, Szeri A J 2002 Phys. Fluids 14 2216Google Scholar
[27] Doinikov A A 2004 J. Fluid Mech. 501 1Google Scholar
[28] Mettin R, Doinikov A A 2009 Appl. Acoust. 70 1330Google Scholar
[29] 刘式适, 刘式达 2002 特殊函数 (第二版) (北京: 气象出版社) 第255, 237−240, 247−251页
Liu S S, Liu S D 2002 Special Function (2nd Ed.) (Beijing: Qixiang Press) pp255, 237−240, 247−251 (in Chinese)
[30] Franc J P, Michel J M 2004 Fundamentals of Cavitation (Nether- lands: Kluwer Academic Publisher) p341
[31] Plesset M S 1949 J. Appl. Mech. 16 277Google Scholar
[32] 陈伟中 2014 声空化物理 (北京: 科学出版社) 第250−253页
Chen W Z 2014 Physics of Acoustic Cavitation (Beijing: Science Press) pp250−253 (in Chinese)
[33] Tsiglifis K, Pelekasi N A 2005 Phys. Fluids 17 102101Google Scholar
[34] Kostas T, Pelekasis N A 2007 Ultrason. Sonochem. 14 456Google Scholar
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