Suppression of turbulent resistivity in turbulent Couette flow

Suppression of turbulent resistivity in turbulent Couette flow

Turbulent transport in rapidly rotating shear flow very efficiently transports angular momentum, a critical feature of instabilities responsible both for the dynamics of accretion disks and the turbulent power dissipation in a centrifuge. Turbulent mixing can efficiently transport other quantities l...

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Veröffentlicht in:Physics of plasmas 2015-07, Vol.22 (7)
Hauptverfasser: Si, Jiahe, Colgate, Stirling A., Sonnenfeld, Richard G., Nornberg, Mark D., Li, Hui, Colgate, Arthur S., Westpfahl, David J., Romero, Van D., Martinic, Joe
Format: Artikel
Sprache:eng
Schlagworte:
70 PLASMA PHYSICS AND FUSION TECHNOLOGY
ACCRETION DISKS
ANGULAR MOMENTUM
CENTRIFUGES
COUETTE FLOW
Differential rotation
Electrical resistivity
Enhanced diffusion
FLUCTUATIONS
Fluid dynamics
Fluid flow
High Reynolds number
INSTABILITY
LIQUID METALS
MAGNETIC FIELDS
MAGNETIC FLUX
NEW MEXICO
Plasma physics
REYNOLDS NUMBER
ROTATING PLASMA
Rotation
SHEAR
Shear flow
Transport
TURBULENT FLOW
Turbulent mixing
Variation
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Zusammenfassung:Turbulent transport in rapidly rotating shear flow very efficiently transports angular momentum, a critical feature of instabilities responsible both for the dynamics of accretion disks and the turbulent power dissipation in a centrifuge. Turbulent mixing can efficiently transport other quantities like heat and even magnetic flux by enhanced diffusion. This enhancement is particularly evident in homogeneous, isotropic turbulent flows of liquid metals. In the New Mexico dynamo experiment, the effective resistivity is measured using both differential rotation and pulsed magnetic field decay to demonstrate that at very high Reynolds number rotating shear flow can be described entirely by mean flow induction with very little contribution from correlated velocity fluctuations.
ISSN:1070-664X
1089-7674
DOI:10.1063/1.4926582