Abstract
This article presents some results on the statistical behavior of localized structures—called “spots”—that propagate in the flow between a rotating and a stationary disk when those are very close one to the other. Under these conditions the rotating-disk flow belongs to the Couette-flow family and is called the torsional Couette flow. Some visualizations of its transition to turbulence have already revealed the propagation of these spots (Schouveiler et al., J Fluid Mech 443:329–350, 2001) from the rim of the disk towards its center. Using flow visualizations and an original image analysis, the present study aims to better describe the characteristics of the spots whose number continuously increases with the Reynolds number until they invade the whole flow. Moreover, we propose a statistical model that predicts an error-function shape for the probability to observe a spot at a given radial position. This prediction is confirmed by an image analysis of the flow and the stability curve of torsional Couette flow is deduced from these observations.
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Gal, P.L., Tasaka, Y., Nagao, J. et al. A statistical study of spots in torsional Couette flow. J Eng Math 57, 289–302 (2007). https://doi.org/10.1007/s10665-006-9100-z
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DOI: https://doi.org/10.1007/s10665-006-9100-z