Experimental and numerical investigation of reactive species transport around a small rising bubble

Abstract: In this article, we present experimental and numerical techniques to investigate the transfer, transport, and reaction of a chemical species in the vicinity of rising bubbles. In the experiment, single oxygen bubbles of diameter d b = 0.55 . . . 0.85 mm are released into a measurement cell filled with tap water. The oxygen dissolves and reacts with sulfite to sulfate. Laser-induced fluorescence is used to visualize the oxygen concentration in the bubble wake from which the global mass transfer coefficient can … Show more

“…In particular, the Marangoni stresses at a drop surface that result from buoyancy-induced motion strongly reduce the settling velocity as compared to clean conditions [3][4][5][6][7]. The presence of adsorbed contaminants leads generally to discrepancy between experimental observations and simulation predictions [8,9], making difficult the establishment of reliable predictive laws. However, measuring minute interfacial concentrations of a droplet is challenging and beyond the reach of previous experimental techniques.…”

Determination of Interfacial Concentration of a Contaminated Droplet from Shape Oscillation Damping

“…In particular, the Marangoni stresses at a drop surface that result from buoyancy-induced motion strongly reduce the settling velocity as compared to clean conditions [3][4][5][6][7]. The presence of adsorbed contaminants leads generally to discrepancy between experimental observations and simulation predictions [8,9], making difficult the establishment of reliable predictive laws. However, measuring minute interfacial concentrations of a droplet is challenging and beyond the reach of previous experimental techniques.…”

Determination of Interfacial Concentration of a Contaminated Droplet from Shape Oscillation Damping

“…A single adjustable parameter assures that the cell average of the analytical solution is in agreement with cell‐centered values coming from the FV discretization. This local adjustment is very accurate and robust .…”

“…For the SGS modeling of reactive‐species boundary layers, the substitute problem needs to be modified in several aspects: (1) Along a planar interface, the boundary layer of the transfer species reaches a steady state when diffusion and reaction are in equilibrium. Therefore, it becomes more difficult and sometimes impossible to adjust the profile to a more complex setting such as a rising bubble . To overcome this limitation, convection in the direction normal to the interface must be included.…”

“…Reactive‐species boundary layers, however, are more complicated because several chemical species may interact in a reaction. Additionally, the asymptotic behavior of the reactive planar 2D problem mentioned before is not sufficient to explain transport mechanisms encountered at a rising bubble .…”

“…They reported maximum errors of 4 % for the integral mass transfer and a wide range of Sc numbers ( Sc = 10 2 to 10 4 ). The advantage of such SGS models is not only the improved accuracy but also the ability to investigate coupled phenomena, e.g., the influence of surface contamination on hydrodynamics and mass transfer , , whereby the correct ratio of different timescales is essential.…”

Data‐Driven Subgrid‐Scale Modeling for Convection‐Dominated Concentration Boundary Layers

Assessment of a subgrid‐scale model for convection‐dominated mass transfer for initial transient rise of a bubble