The history effect on bubble growth and dissolution. Part 2. Experiments and simulations of a spherical bubble attached to a horizontal flat plate

Peñas, Pablo; Soto, Álvaro Moreno; Parrales, Miguel A.; Meer, Devaraj van der; Lohse, Detlef; Rodríguez-Rodríguez, Javier

doi:10.1017/jfm.2017.221

Cited by 22 publications

(16 citation statements)

References 28 publications

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“…1(b), the ambient bubble radius R 0 (defined as the mean sphere-equivalent radius about which the bubble oscillates) grows by diffusion until it approaches the resonant size. The early growth dynamics are well predicted by the classical Epstein-Plesset theory for diffusive growth [27] despite some deviations which can be attributed to perturbations in the initial condition of the concentration field [28]. Taking into account the presence of the substrate, the asymptotic solution reads…”

Section: Growth Dynamicsmentioning

confidence: 68%

Ultrasound-enhanced mass transfer during single-bubble diffusive growth

et al. 2020

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Ultrasound is known to enhance surface bubble growth and removal in catalytic and microfluidic applications, yet the contributions of rectified diffusion and microstreaming phenomena toward mass transfer remain unclear. We quantify the effect of ultrasound on the diffusive growth of a single spherical CO 2 bubble growing on a substrate in supersaturated water. The time-dependent bubble size, shape, oscillation amplitude, and microstreaming flow field are resolved. We show and explain how ultrasound can enhance the diffusive growth of surface bubbles by up to two orders of magnitude during volumetric resonance. The proximity of the wall forces the bubble to oscillate nonspherically, thereby generating vigorous streaming during resonance that results in convection-dominated growth.

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Section: Growth Dynamicsmentioning

confidence: 68%

Ultrasound-enhanced mass transfer during single-bubble diffusive growth

et al. 2020

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“…namely, the atmospheric pressure far from the bubble (P ∞ ), the hydrodynamic pressure induced by the fluid motion (P h ), and the capillary pressure (P γ ). The latter is retained here, in contrast to most analytical derivations on bubble dissolution and growth [25,29], effectively restricting their results to bubble radii greater than 1-10 µm, and therefore excluding the final stages of the bubble's life. In the following, we assume that hydrodynamic pressure is negligible; when the fluid motion results from the bubble collapse, this effectively assumes that the Capillary number, Ca = ηṘ/γ, is always small, i.e.Ṙ γ/η ≈ 70 m.s −1 for water under normal conditions.…”

Section: Dissolution Of An Isolated Microbubblementioning

confidence: 99%

“…This shows that the potential part u pot does not contribute to the force that is solely given in terms of the viscous contribution and can be computed directly using Stimson's result as in Eq. (29).…”

Section: Appendix C: Viscous Flow Outside Two Growing/shrinking Bubblesmentioning

confidence: 99%

“…For most gases under ambient conditions, diffusion of the dissolved gas is much faster than the evolution in the bubble radius due to the molar density contrast between the concentration of gas in the bubble and in the liquid [26]. As a result, transient and convective effects are essentially negligible except initially or when fluctuations in the background pressure are taken into account [27][28][29]. This is in stark contrast with the heat-driven dynamics of vapour bubbles for which both time-scales are comparable and inertial effects can be significant [30], or with gas bubbles with comparable concentrations in both phases [31].…”

Section: Introductionmentioning

confidence: 99%

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Collective dissolution of microbubbles

2018

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A microscopic bubble of soluble gas always dissolves in finite time in an under-saturated fluid. This diffusive process is driven by the difference between the gas concentration near the bubble, whose value is governed by the internal pressure through Henry's law, and the concentration in the far field. The presence of neighbouring bubbles can significantly slow down this process by increasing the effective background concentration and reducing the diffusing flux of dissolved gas experienced by each bubble. We develop theoretical modelling of such diffusive shielding process in the case of small microbubbles whose internal pressure is dominated by Laplace pressure. We first use an exact semi-analytical solution to capture the case of two bubbles and analyse in detail the shielding effect as a function of the distance between the bubbles and their size ratio. While we also solve exactly for the Stokes flow around the bubble, we show that hydrodynamic effects are mostly negligible except in the case of almost-touching bubbles. In order to tackle the case of multiple bubbles, we then derive and validate two analytical approximate yet generic frameworks, first using the method of reflections and then by proposing a self-consistent continuum description. Using both modelling frameworks, we examine the dissolution of regular one-, two-and three-dimensional bubble lattices. Bubbles located at the edge of the lattices dissolve first, while innermost bubbles benefit from the diffusive shielding effect, leading to the inward propagation of a dissolution front within the lattice. We show that diffusive shielding leads to severalfold increases in the dissolution time which grows logarithmically with the number of bubbles in one dimensional lattices and algebraically in two and three dimensions, scaling respectively as its square root and 2/3-power. We further illustrate the sensitivity of the dissolution patterns to initial fluctuations in bubble size or arrangement in the case of large and dense lattices, as well as non-intuitive oscillatory effects.

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“…perturbations in the initial condition of the concentration field [27]. Taking into account the presence of the substrate, the asymptotic solution reads [28]…”

Section: Growth Dynamicsmentioning

confidence: 99%

Ultrasound-enhanced mass transfer during single-bubble diffusive growth

Soto,

Peñas,

Lajoinie

et al. 2020

Preprint

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Ultrasound is known to enhance surface bubble growth and removal in catalytic and microfluidic applications, yet the contributions of rectified diffusion and microstreaming phenomena towards mass transfer remain unclear. We quantify the effect of ultrasound on the diffusive growth of a single spherical CO 2 bubble growing on a substrate in supersaturated water. The time dependent bubble size, shape, oscillation amplitude and microstreaming flow field are resolved. We show and explain how ultrasound can enhance the diffusive growth of surface bubbles by up to two

show abstract

The history effect on bubble growth and dissolution. Part 2. Experiments and simulations of a spherical bubble attached to a horizontal flat plate

Cited by 22 publications

References 28 publications

Ultrasound-enhanced mass transfer during single-bubble diffusive growth

Ultrasound-enhanced mass transfer during single-bubble diffusive growth

Collective dissolution of microbubbles

Ultrasound-enhanced mass transfer during single-bubble diffusive growth

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