Collapse and rebound of a laser-induced cavitation bubble

Akhatov, Iskander; Lindau, Olgert; Topolnikov, A.S.; Mettin, Robert; Vakhitova, N. K.; Lauterborn, Werner

doi:10.1063/1.1401810

Cited by 426 publications

(277 citation statements)

References 49 publications

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“…For instance, in the time interval between 80 and 100 µs during which the jet impact occurs in the simulations of figure 15, the average gas pressure in bubble 2 is of the order of 0.2 bar. That is about eight times larger than the equilibrium water vapour pressure at room temperature, which is usually assumed to prevail in an expanded cavitation bubble (Akhatov et al 2001). Therefore, we refrain from quoting explicit values of the gas pressure and only describe the general features of the gas flow accompanying jet formation.…”

Section: Discussionmentioning

confidence: 99%

“…Since the jet impact occurs when bubble 2 is maximally expanded, the bubble pressure will probably be close to the equilibrium water vapour pressure at room temperature, i.e. of the order of 25 mbar (Akhatov et al 2001). Therefore, jet entry will differ from the impact of a liquid jet onto a water surface in air (Kersten, Ohl & Prosperetti 2003).…”

Section: Jet Dynamicsmentioning

confidence: 99%

“…Dynamics of laser-induced bubble pairs 707 et al 1992; Putterman & Weninger 2000;Akhatov et al 2001;Brenner, Hilgenfeldt & Lohse 2002;Suslick & Flannigan 2008;Lauterborn & Kurz 2010;Schanz et al 2012). However, spherical-bubble collapse requires isotropic bubble surroundings and inherent stability conditions to be fulfilled with respect to spherical shape (parametric and Rayleigh-Taylor instability) (Plesset 1954;Strube 1971;Hilgenfeldt, Lohse & Brenner 1996;Ohl, Lindau & Lauterborn 1998;Lauterborn et al 1999;Ohl et al 1999;Lin, Storey & Szeri 2002;Koch et al 2011).…”

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confidence: 99%

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Dynamics of laser-induced bubble pairs

et al. 2015

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The interaction of two laser-induced bubbles in bulk water is investigated. The strength and direction of the emerging liquid jets can be controlled by adjusting the relative bubble positions, the time difference between bubble generation, and the laser pulse energies determining the bubble sizes. Experimental and numerical studies are performed for millimetre-sized bubble pairs. Taking bubbles of equal energy, a maximum jet velocity is found for close anti-phase bubbles, i.e. when the second bubble is produced at the maximum volume of the first one and the bubble walls are almost touching and not merging. Under these conditions, one bubble produces a fast jet with a peak velocity of about 150 m s −1 that reaches a distance into the surrounding liquid of at least three times the maximum bubble radius. Collapse of the other bubble results in a slow jet of large mass that rapidly converts into a ring vortex. Correspondingly, the interaction with adjacent structures is dominated either by localized jet impact or by shear stresses extending over a larger area. Furthermore, interactions between micrometre-sized bubble pairs are investigated numerically to understand and predict how the effects of the physical parameters on bubble dynamics would change when the bubbles become smaller. The results are discussed with respect to micropumping and opto-injection.

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Section: Discussionmentioning

confidence: 99%

Section: Jet Dynamicsmentioning

confidence: 99%

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confidence: 99%

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Dynamics of laser-induced bubble pairs

et al. 2015

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“…Different and more sophisticated variants of equation (5.9) are available in the literature to take into account other effects, such as: the evaporation and diffusion flow rates of vapour and gas through the bubble walls [79,103,104], temperature discontinuity at the bubble surface between the aeriform constituents and the liquid phase [105], the kinematic slip condition between the liquid and vapour phases [105,106] as well as liquid compressibility [107,108]. The temperature, pressure and velocity differences between the different phases can be simulated in two-phase models, in which a Rayleigh-Plesset-type equation is coupled to the mass and momentum conservation and partial differential equations for each distinct phase [11].…”

Section: (A) the Rayleigh-plesset Equation For Single-bubble Dynamicsmentioning

confidence: 99%

Fluid dynamics of acoustic and hydrodynamic cavitation in hydraulic power systems

Ferrari¹

2017

Proc. R. Soc. A.

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Cavitation is the transition from a liquid to a vapour phase, due to a drop in pressure to the level of the vapour tension of the fluid. Two kinds of cavitation have been reviewed here: acoustic cavitation and hydrodynamic cavitation. As acoustic cavitation in engineering systems is related to the propagation of waves through a region subjected to liquid vaporization, the available expressions of the sound speed are discussed. One of the main effects of hydrodynamic cavitation in the nozzles and orifices of hydraulic power systems is a reduction in flow permeability. Different discharge coefficient formulae are analysed in this paper: the Reynolds number and the cavitation number result to be the key fluid dynamical parameters for liquid and cavitating flows, respectively. The latest advances in the characterization of different cavitation regimes in a nozzle, as the cavitation number reduces, are presented. The physical cause of choked flows is explained, and an analogy between cavitation and supersonic aerodynamic flows is proposed. The main approaches to cavitation modelling in hydraulic power systems are also reviewed: these are divided into homogeneous-mixture and twophase models. The homogeneous-mixture models are further subdivided into barotropic and baroclinic models. The advantages and disadvantages of an implementation of the complete Rayleigh-Plesset equation are examined.

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“…This intriguing phenomenon has versa-tile applications ranging from nanoparticle synthesis [1,2], surface cleaning [3] to luminescence [4]. The dynamics of cavitation bubble is of central importance since it reflects the fundamental response of liquid-plasma-solid system to laser ablation, and thus has drawn increasing interest [5][6][7][8]. Usually, the conventional Rayleigh-Plesset (R-P) theory is modified to reproduce the ablation-induced bubble dynamics.…”

Section: Introductionmentioning

confidence: 99%