Inhibition of wave-driven two-dimensional turbulence by viscoelastic films of proteins

To model waves, surface flows, and particle dispersion at the air-water interface one needs to know the essential mechanisms affecting the fluid motion at the surface. We show that a thin film (less than 10-nm thick) of adsorbed protein dramatically affects two-dimensional turbulence generated by Faraday waves at the fluid surface. Extremely low concentrations (≈1 ppm) of soluble proteins form a strong viscoelastic layer which suppresses turbulent diffusion at the surface, changes wave patterns, and shows strong resilience to the wave-induced droplet generation. Surface shear properties of the film play a key role in this phenomenon by inhibiting the creation of vorticity at the surface. The addition of surfactants, on the other hand, destroys the nanolayer and restores the fluid mobility

Bubble-based acoustic micropropulsors: active surfaces and mixers.

Acoustic micropropulsors present great potential for microfluidic applications. The propulsion is based on encapsulated 20 μm bubbles excited by a contacless ultrasonic transducer. The vibrating bubbles then generate a powerful streaming flow, with speeds 1-100 mm s-1 in water, through the action of viscous stresses. In this paper we introduce a full toolbox of micropropulsors using a versatile three-dimensional (3D) microfabrication setup. Doublets and triplets of propulsors are introduced, and the flows they generate are predicted by a theoretical hydrodynamic model. We then introduce whole surfaces covered with propulsors, which we term active surfaces. These surfaces are excited by a single ultrasonic wave, can generate collective flows and may be harnessed for mixing purposes. Several patterns of propulsors are tested, and the flows produced by the two most efficient mixers are predicted by a simple theoretical model based on flow singularities. In particular, the vortices generated by the most efficient pattern, an L-shaped mixer, are analysed in detail.P. M. acknowledges financial support from the European Community's Seventh Framework Programme (FP7/2007- 2013) ERC Grant Agreement Bubbleboost no. 614655. This work has been performed with the help of the “Plateforme Technologique Amont” de Grenoble, with the financial support of the “Nanosciences aux limites de la Nanoélectronique” foundation. This work was partially funded through a Marie Curie CIG grant (EL) and through EPSRC (TS)

Etude d'une assemblée de bulles microfluidiques excitées par une onde ultrasonore : transmission acoustique et phénomène de streaming

Because of the important compressibility of gas bubbles in water, inducing a very low resonance frequency, one can find interest in studying bubbles from an acoustic and a fluid mechanics point of view. Using microfluidics techniques in order to produce assemblies of acoustically driven bi-dimensional bubbles, we are studying their influence on both acoustic waves and the surrounding fluid.Bubbles being sub-wavelength resonators, we show that a micro-bubbles assembly interacts with acoustical waves which wavelengths that are substantially bigger than the bubbles size. Developing a way to extract bubbles contribution to the acoustic signal, we show that their resonance frequency follows a law slightly different from the one Minnaert had found for spherical bubbles. The impact of this medium on the acoustical wave has been studied and we show that a decrease in the acoustical transmission happens in a range of frequencies above the resonance. This decrease can be adjusted in amplitude and in frequency making our system an easily tunable metameterial.Because of the strong response of bubbles induced by acoustical waves, the bubbles surface oscillates with a great amplitude in the surrounding fluid. This oscillation, working together with a coupling present between the bubbles, can drive a strong steady streaming in the fluid. Systems of several bubbles are studied, and a theory is proposed in order to predict the flow they induce. The interaction between the streaming phenomenon and an external flow is also presented, showing that exclusion zones can be present under certain circumstances in these systems. These exclusion zones can be useful in micro-fluidics in order to trap particles or chemicals.De par leur importante compressibilité et leur fréquence de résonance extrêmement basse, les bulles sont des objets physiques singuliers du point de vue de l'acoustique et de la mécanique des fluides. En utilisant la technique de la microfluidique afin de créer des assemblées de bulles bi-dimensionnelles, que nous excitons acoustiquement, nous étudions à la fois leur influence sur une onde sonore et sur le fluide présent à leur voisinage.Les bulles étant des résonateurs sub-longueur d'onde, nous montrons qu'une assemblée de micro-bulles va interagir avec une onde sonore de longueur d'onde bien plus importante que la taille des bulles individuelles. En proposant une méthode pour extraire la contribution des bulles au signal acoustique, nous montrons que leur résonance suit une loi légèrement modifiée par rapport à celle proposée par Minnaert pour des bulles sphériques.Nous avons également exploré le potentiel de ce système expérimental comme méta-matériau pour l'acoustique. Nous observons en effet une baisse de la transmission d'une onde sonore à travers ce matériau et ce, dans une gamme de fréquence située au-delà de la fréquence de résonance.Cette baisse de la transmission peut être ajustée à la fois en fréquence et en amplitude ce qui fait de ce système un méta-matériau adaptable dont les caractéristiques peuvent être facilement ajustées

Study of ultrasonic driven microfluidics bubbles : acoustic transmission and streaming phenomenon

De par leur importante compressibilité et leur fréquence de résonance extrêmement basse, les bulles sont des objets physiques singuliers du point de vue de l'acoustique et de la mécanique des fluides. En utilisant la technique de la microfluidique afin de créer des assemblées de bulles bi-dimensionnelles, que nous excitons acoustiquement, nous étudions à la fois leur influence sur une onde sonore et sur le fluide présent à leur voisinage.Les bulles étant des résonateurs sub-longueur d'onde, nous montrons qu'une assemblée de micro-bulles va interagir avec une onde sonore de longueur d'onde bien plus importante que la taille des bulles individuelles. En proposant une méthode pour extraire la contribution des bulles au signal acoustique, nous montrons que leur résonance suit une loi légèrement modifiée par rapport à celle proposée par Minnaert pour des bulles sphériques.Nous avons également exploré le potentiel de ce système expérimental comme méta-matériau pour l'acoustique. Nous observons en effet une baisse de la transmission d'une onde sonore à travers ce matériau et ce, dans une gamme de fréquence située au-delà de la fréquence de résonance.Cette baisse de la transmission peut être ajustée à la fois en fréquence et en amplitude ce qui fait de ce système un méta-matériau adaptable dont les caractéristiques peuvent être facilement ajustées.Because of the important compressibility of gas bubbles in water, inducing a very low resonance frequency, one can find interest in studying bubbles from an acoustic and a fluid mechanics point of view. Using microfluidics techniques in order to produce assemblies of acoustically driven bi-dimensional bubbles, we are studying their influence on both acoustic waves and the surrounding fluid.Bubbles being sub-wavelength resonators, we show that a micro-bubbles assembly interacts with acoustical waves which wavelengths that are substantially bigger than the bubbles size. Developing a way to extract bubbles contribution to the acoustic signal, we show that their resonance frequency follows a law slightly different from the one Minnaert had found for spherical bubbles. The impact of this medium on the acoustical wave has been studied and we show that a decrease in the acoustical transmission happens in a range of frequencies above the resonance. This decrease can be adjusted in amplitude and in frequency making our system an easily tunable metameterial.Because of the strong response of bubbles induced by acoustical waves, the bubbles surface oscillates with a great amplitude in the surrounding fluid. This oscillation, working together with a coupling present between the bubbles, can drive a strong steady streaming in the fluid. Systems of several bubbles are studied, and a theory is proposed in order to predict the flow they induce. The interaction between the streaming phenomenon and an external flow is also presented, showing that exclusion zones can be present under certain circumstances in these systems. These exclusion zones can be useful in micro-fluidics in order to trap particles or chemicals

Effect of surface waves on the secondary Bjerknes force experienced by bubbles in a microfluidic channel

International audienceAn analytical expression is derived for the secondary Bjerknes force experienced by two cylindrical bubbles in a microfluidic channel with planar elastic walls. The derived expression takes into account that the bubbles generate two types of scattered acoustic waves: bulk waves that propagate in the fluid gap with the speed of sound and Lamb-type surface waves that propagate at the fluid-wall interfaces with a much lower speed than that of the bulk waves. It is shown that the surface waves cause the bubbles to form a bound pair in which the equilibrium interbubble distance is determined by the wavelength of the surface waves, which is much smaller than the acoustic wavelength. Comparison of theoretical and experimental results demonstrates good agreement

Acoustic streaming produced by a cylindrical bubble undergoing volume and translational oscillations in a microfluidic channel

International audienceA theoretical model is developed for acoustic streaming generated by a cylindrical bubble confined in a fluid channel between two planar elastic walls. The bubble is assumed to undergo volume and translational oscillations. The volume oscillation is caused by an imposed acoustic pressure field and generates the bulk scattered wave in the fluid gap and Lamb-type surface waves propagating along the fluid-wall interfaces. The translational oscillation is induced by the velocity field of an external sound source such as another bubble or an oscillatory fluid flow. The acoustic streaming is assumed to result from the interaction of the volume and the translational modes of the bubble oscillations. The general solutions for the linear equations of fluid motion and the equations of acoustic streaming are calculated with no restrictions on the ratio between the viscous penetration depth and the bubble size. Approximate solutions for the limit of low viscosity are provided as well. Simulations of streamline patterns show that the geometry of the streaming resembles flows generated by a source dipole, while the vortex orientation is governed by the driving frequency, bubble size, and the distance of the bubble from the source of translational excitation. Experimental verification of the developed theory is performed using data for streaming generated by bubble pairs

Trapping and exclusion zones in complex streaming patterns around a large assembly of microuidic bubbles under ultrasound

International audiencePulsating bubbles have proved to be a versatile tool for trapping and sorting particles. In this article, we investigate the dierent streaming patterns that can be obtained with a group of bubbles in a conned geometry under ultrasound. In the presence of an external ow strong enough to oppose the streaming velocities but not to drag the trapped bubbles, we observe either the appearance of exclusion zones near the bubbles or asymmetric streaming patterns that we interpret as the superposition of a 2D streaming function and of a potential ow. When studying a lattice of several bubbles, we show that the streaming pattern can be accurately predicted by superimposing the contributions of every pair of bubbles present in the lattice, thus allowing one to predict the sizes and the shapes of exclusion zones created by a group of bubbles under acoustic excitation. We suggest that such systems could be used to enhance mixing at small scale, or to catch and release chemical species initially trapped in vortices created around bubble pairs

Interactions enhance the acoustic streaming around flattened microfluidic bubbles

International audienceThe vibration of bubbles can produce intense microstreaming when excited by ultrasound near resonance. In order to study freely oscillating bubbles in steady conditions, we have confined bubbles between the two walls of a silicone microchannel and anchored them on micropits. We were thus able to analyse the microstreaming flow generated around an isolated bubble or a pair of interacting bubbles. In the case of an isolated bubble, a short-range microstreaming occurs in the channel gap, with additional in-plane vortices at high amplitude when Faraday waves are excited on the bubble periphery. For a pair of bubbles, we have observed long-range microstreaming and large recirculations describing a 'butterfly' pattern. We propose a model based on secondary acoustic Bjerknes forces mediated by Rayleigh waves on the silicone walls. These forces lead to attraction or repulsion of bubbles and thus to the excitation of a translational mode in addition to the breathing mode of the bubble. The mixed-mode streaming induced by the interaction of these two modes is shown to generate fountain or anti-fountain vortex pairs, depending on the relative distance between the bubbles

Acoustic interaction between 3D fabricated cubic bubbles

International audienceSpherical bubbles are notoriously difficult to hold in specific arrangements in water and tend to dissolve over time. Here, using stereolithographic printing, we built an assembly of millimetric cubic frames overcoming these limitations. Indeed, each of these open frames holds an air bubble when immersed into water, resulting in bubbles that are stable for long times and still able to oscillate acoustically. Several bubbles can be placed in any wanted spatial arrangement thanks to the fabrication process. We show that bubbles are coupled acoustically when disposed along lines, planes or 3D arrangement, and that their collective resonance frequency is shifted to much lower values, especially for 3D arrangements where bubbles have higher number of close neighbours. Considering that these cubic bubbles behave acoustically as spherical bubbles of the same volume , we develop a theory allowing to predict the acoustical emission of any arbitrary group of bubbles, in agreement with experiments

Music for Cells? A Systematic Review of Studies Investigating the Effects of Audible Sound Played Through Speaker-Based Systems on Cell Cultures

There have been several studies investigating whether musical sound can be used as cell stimuli in recent years. We systematically searched publications to get an overview of studies that have used audible sound played through speaker-based systems to induce mechanical perturbation in cell cultures. A total of 12 studies were identified. We focused on the experimental setups, the sounds that were used as stimuli, and relevant biological outcomes. The studies are categorized into simple and complex sounds depending on the type of sound employed. Some of the promising effects reported were enhanced cell migration, proliferation, colony formation, and differentiation ability. However, there are significant differences in methodologies and cell type-specific outcomes, which made it difficult to find a systematic pattern in the results. We suggest that future experiments should consider using: (1) a more controlled acoustic environment, (2) standardized sound and noise measurement methods, and (3) a more comprehensive range of controlled sound parameters as cellular stimuli