Stout beers show the counter-intuitive phenomena of sinking bubbles, while the beer is settling. Previous research suggests that this phenomenon is due to the small size of the bubbles in these beers and the presence of a circulatory current, directed downwards near the side of the wall and upwards in the interior of the glass. The mechanism by which such a circulation is established and the conditions under which it will occur has not been clarified. In this paper, we use simulations and experiments to demonstrate that the flow in a glass of stout beer depends on the shape of the glass. If it narrows downwards (as the traditional stout glass, the pint, does), the flow is directed downwards near the wall and upwards in the interior and sinking bubbles will be observed. If the container widens downwards, the flow is opposite to that described above and only rising bubbles will be seen.

Topics
Convex geometry, Finite-element analysis, Gas liquid interfaces, Educational assessment, Flow simulations, Laminar flows, Speed of sound, Blood cells, Physicists, Public policy and governance
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A video of this experiment is available as supplementary material from http://dx.doi.org/10.1119/1.4769377.
© 2013 American Association of Physics Teachers.
2013
American Association of Physics Teachers

Supplementary Material

Supplementary Material- zip file
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