Rayleigh's equation (fluid dynamics)

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In fluid dynamics, Rayleigh's equation or Rayleigh stability equation is a linear ordinary differential equation to study the hydrodynamic stability of a parallel, incompressible and inviscid shear flow. The equation is:[1]

Example of a parallel shear flow.

with the flow velocity of the steady base flow whose stability is to be studied and is the cross-stream direction (i.e. perpendicular to the flow direction). Further is the complex valued amplitude of the infinitesimal streamfunction perturbations applied to the base flow, is the wavenumber of the perturbations and is the phase speed with which the perturbations propagate in the flow direction. The prime denotes differentiation with respect to

Background

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The equation is named after Lord Rayleigh, who introduced it in 1880.[2] The Orr–Sommerfeld equation – introduced later, for the study of stability of parallel viscous flow – reduces to Rayleigh's equation when the viscosity is zero.[3]

Rayleigh's equation, together with appropriate boundary conditions, most often poses an eigenvalue problem. For given (real-valued) wavenumber   and mean flow velocity   the eigenvalues are the phase speeds   and the eigenfunctions are the associated streamfunction amplitudes   In general, the eigenvalues form a continuous spectrum. In certain cases there may further be a discrete spectrum of complex conjugate pairs of   Since the wavenumber   occurs only as a square   in Rayleigh's equation, a solution (i.e.   and  ) for wavenumber   is also a solution for the wavenumber  [3]

Rayleigh's equation only concerns two-dimensional perturbations to the flow. From Squire's theorem it follows that the two-dimensional perturbations are less stable than three-dimensional perturbations.

 
Kelvin's cat's eye pattern of streamlines near a critical layer.

If a real-valued phase speed   is in between the minimum and maximum of   the problem has so-called critical layers near   where   At the critical layers Rayleigh's equation becomes singular. These were first being studied by Lord Kelvin, also in 1880.[4] His solution gives rise to a so-called cat's eye pattern of streamlines near the critical layer, when observed in a frame of reference moving with the phase speed  [3]

Derivation

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Consider a parallel shear flow   in the   direction, which varies only in the cross-flow direction  [1] The stability of the flow is studied by adding small perturbations to the flow velocity   and   in the   and   directions, respectively. The flow is described using the incompressible Euler equations, which become after linearization – using velocity components   and  

 

with   the partial derivative operator with respect to time, and similarly   and   with respect to   and   The pressure fluctuations   ensure that the continuity equation   is fulfilled. The fluid density is denoted as   and is a constant in the present analysis. The prime   denotes differentiation of   with respect to its argument  

The flow oscillations   and   are described using a streamfunction   ensuring that the continuity equation is satisfied:

 

Taking the  - and  -derivatives of the  - and  -momentum equation, and thereafter subtracting the two equations, the pressure   can be eliminated:

 

which is essentially the vorticity transport equation,   being (minus) the vorticity.

Next, sinusoidal fluctuations are considered:

 

with   the complex-valued amplitude of the streamfunction oscillations, while   is the imaginary unit ( ) and   denotes the real part of the expression between the brackets. Using this in the vorticity transport equation, Rayleigh's equation is obtained.

The boundary conditions for flat impermeable walls follow from the fact that the streamfunction is a constant at them. So at impermeable walls the streamfunction oscillations are zero, i.e.   For unbounded flows the common boundary conditions are that  

Notes

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  1. ^ a b Craik (1988, pp. 21–27)
  2. ^ Rayleigh (1880)
  3. ^ a b c Drazin (2002, pp. 138–154)
  4. ^ Kelvin (1880)

References

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  • Craik, A.D.D. (1988), Wave interactions and fluid flows, Cambridge University Press, ISBN 0-521-36829-4
  • Criminale, W.O.; Jackson, T.L.; Joslin, R.D. (2003), Theory and computation of hydrodynamic stability, Cambridge University Press, ISBN 978-0-521-63200-3
  • Drazin, P.G. (2002), Introduction to hydrodynamic stability, Cambridge University Press, ISBN 0-521-00965-0
  • Hirota, M.; Morrison, P.J.; Hattori, Y. (2014), "Variational necessary and sufficient stability conditions for inviscid shear flow", Proceedings of the Royal Society, 470 (20140322): 23 pp, arXiv:1402.0719, Bibcode:2014RSPSA.47040322H, doi:10.1098/rspa.2014.0322, PMC 4241005, PMID 25484600
  • Kelvin, Lord (W. Thomson) (1880), "On a disturbing infinity in Lord Rayleigh's solution for waves in a plane vortex stratum", Nature, 23 (576): 45–6, Bibcode:1880Natur..23...45., doi:10.1038/023045a0
  • Rayleigh, Lord (J.W. Strutt) (1880), "On the stability, or instability, of certain fluid motions", Proceedings of the London Mathematical Society, 11: 57–70