Erratum: Nonlinear transport processes and fluid dynamics: Cylindrical Couette flow of Lennard-Jones fluids

Linear stability analysis is carried out for cylindrical Couette flow of a Lennard–Jones fluid in the density range from the dense liquid to the dilute gas regime. Generalized hydrodynamic equations are used to calculate marginal stability curves and compare them with those obtained by using the Navier–Stokes–Fourier equations for compressible fluids and also for incompressible fluids. In the low Reynolds or Mach number regime, if the Knudsen number is sufficiently low, the marginal stability curves calculated by the generalized hydrodynamic theory coincide, within numerical errors, with those based on the Navier–Stokes theory. But there are considerable deviations between them in the regimes beyond those mentioned earlier, since nonlinear effects manifest themselves in the laminar mean flow through the nonlinear dissipation term and normal stresses. There are three marginal stability curves obtained in contrast to the Navier–Stokes theory, which yields only two. The previously observed phase-transition-like behavior in fluid variables and the slip phenomenon are found to occur beyond the hydrodynamic stability point. The disturbance entropy production associated with the Taylor–Couette vortices is calculated to first order in disturbances in flow variables and is found to decrease as the number of vortices increases and thereby the dynamic structure is progressively more organized.

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Nonlinear transport processes in tokamak plasmas. I. The collisional regimes

Physics of Plasmas ◽

10.1063/1.2939377 ◽

2008 ◽

Vol 15 (6) ◽

pp. 062309 ◽

Cited By ~ 11

Author(s):

Giorgio Sonnino ◽

Philippe Peeters

Keyword(s):

Transport Processes ◽

Tokamak Plasmas ◽

Nonlinear Transport

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A frictional Cosserat model for the slow shearing of granular materials

Journal of Fluid Mechanics ◽

10.1017/s0022112002007796 ◽

2002 ◽

Vol 457 ◽

pp. 377-409 ◽

Cited By ~ 71

Author(s):

L. SRINIVASA MOHAN ◽

K. KESAVA RAO ◽

PRABHU R. NOTT

Keyword(s):

Angular Velocity ◽

Granular Material ◽

Shear Layer ◽

Granular Materials ◽

Layer Thickness ◽

Couette Flow ◽

Velocity Fields ◽

Cosserat Continuum ◽

Cosserat Model ◽

Cylindrical Couette Flow

A rigid-plastic Cosserat model for slow frictional flow of granular materials, proposed by us in an earlier paper, has been used to analyse plane and cylindrical Couette flow. In this model, the hydrodynamic fields of a classical continuum are supplemented by the couple stress and the intrinsic angular velocity fields. The balance of angular momentum, which is satisfied implicitly in a classical continuum, must be enforced in a Cosserat continuum. As a result, the stress tensor could be asymmetric, and the angular velocity of a material point may differ from half the local vorticity. An important consequence of treating the granular medium as a Cosserat continuum is that it incorporates a material length scale in the model, which is absent in frictional models based on a classical continuum. Further, the Cosserat model allows determination of the velocity fields uniquely in viscometric flows, in contrast to classical frictional models. Experiments on viscometric flows of dense, slowly deforming granular materials indicate that shear is confined to a narrow region, usually a few grain diameters thick, while the remaining material is largely undeformed. This feature is captured by the present model, and the velocity profile predicted for cylindrical Couette flow is in good agreement with reported data. When the walls of the Couette cell are smoother than the granular material, the model predicts that the shear layer thickness is independent of the Couette gap H when the latter is large compared to the grain diameter dp. When the walls are of the same roughness as the granular material, the model predicts that the shear layer thickness varies as (H/dp)1/3 (in the limit H/dp [Gt ] 1) for plane shear under gravity and cylindrical Couette flow.

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