Gravity wave instability in a turbulent free-surface Taylor–Couette flow: experiments and comparison with an amplitude equation with additive noise
Author
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Martínez Mercado, J.
Author
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Arratia, Cristóbal
Author
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Falcón Beas, Claudio
Author
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Mujica Fernández, Nicolás
Admission date
dc.date.accessioned
2015-07-08T20:34:12Z
Available date
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2015-07-08T20:34:12Z
Publication date
dc.date.issued
2015
Cita de ítem
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New J. Phys. 17 (2015) 013039
en_US
Identifier
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Doi:10.1088/1367-2630/17/1/013039
Identifier
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https://repositorio.uchile.cl/handle/2250/131870
General note
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Artículo de publicación ISI
en_US
Abstract
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Wepresent an experimental and theoretical study on the gravity-wave instability developing in a
highly turbulent free-surface Taylor–Couette flow, for which only the inner cylinder rotates. Above a
critical rotation speed, from an axisymmetric turbulent base state a non-axisymmetric fluctuating
gravity-wave state develops, with anm= 1 azimuthal wave number. The bifurcation is discontinuous
and presents hysteresis. In contrast to previously reported work (MujicaNand LathropD2006 J. Fluid
Mech. 51 49–62), here we compare our experimental results with a universal model based on a quintic
subcritical amplitude equation with additive noise. In general, the model describes correctly the mean
free-surface oscillation amplitude and its fluctuations, although differences exist in the bistability
region width and the free-surface fluctuations in the gravity wave state. These differences are due to
the finite time measurements and non-linear effects, respectively. Indeed, we show that longer measurement
times allow the system to transit in either direction (from or to the base state), which results
in the shrinking of the bistability region. For very long measurement times, and in a very narrow range
of rotation rates, the system presents a series of random reversals between both states. Finally, by
removing the mean wave and flow oscillations in the measured free-surface and bulk pressure signals,
we demonstrate that their dynamic fluctuations depend on the system state.
en_US
Patrocinador
dc.description.sponsorship
FONDECYT postdoctoral grant no. 3130492, and the CONICYT
grant AIC no. 43.CA