Paris, 22 February 2016
Many natural phenomena and industrial processes, such as foam production, require the formation of thin liquid films, while others require the opposite: preventing bubbles from forming. The latter include glass making and depositing liquid coatings onto plates or fibers. To study soap bubble formation in the laboratory, researchers developed an experimental bubble machine that can produce long-lived thin liquid films.
A tank placed above the setup lets a soap solution flow between two stretched nylon wires. The liquid flows under gravity, and is then pumped back to the tank. When the two wires, each about one meter long, are separated, they form a rectangular soap film. An "artificial mouth" made of a needle connected to a pressure regulator mimics human breathing. At low speed, the gas jet deforms the film and creates a cavity that becomes thinner as the gas rate increases, until the rate reaches the threshold for bubble formation. These rapid phenomena, which are difficult to see with the naked eye, are revealed when filming the experiments with a high-speed camera.
The researchers thus modeled the results as a function of the different experimental configurations. They have identified the key physical factors that control the minimum breathing speed for generating bubbles on a soap film. The team also characterized the influence of the distance separating the "mouth" from the film on bubble formation, then observed that the velocity and thickness of the soap film did not impact bubble production under the conditions studied.
So this work produces excellent data for bubble size and formation frequency measurement. This may help to optimize diverse industrial processes.
To generate soap bubbles, the gas speed (Vg) must be greater than a threshold value Vc (Film 1). For speeds below the threshold, a cavity forms in the self-supporting soap film. The other parameters of the experiment remain the same (Film 2).
Popular Science Short Film "Soap Bubbles" (in French) :
Created in 2014 by Louis Salkin (the lead author on this article, who was then a PhD student at the Institut de Physique de Rennes). This video won the Jury's first prize that year at the Rennes Festival Sciences en cour[t]s.
© L. Salkin et al., Phys. Rev. Lett. (2016). Institut de Physique de Rennes (CNRS/Université Rennes 1).
(a) Typical progression in the cavity created in a film when the gas flow rate Vg increases and is below the minimum value for creating bubbles Vc. (b) Bubbles form when Vg is greater than Vc.
Generating soap bubbles by blowing on soap films. Louis Salkin, Alexandre Schmit, Pascal Panizza, and Laurent Courbin. Physical Review Letters, February 19, 2016.
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