The Orr–Sommerfeld equation, in fluid dynamics, is an eigenvalue equation describing the linear two-dimensional modes of disturbance to a viscous parallel flow. The solution to the Navier–Stokes equations for a parallel, laminar flow can become unstable if certain conditions on the flow are satisfied, and the Orr–Sommerfeld equation determines precisely what the conditions for hydrodynamic stability are.
The equation is named after William McFadden Orr and Arnold Sommerfeld, who derived it at the beginning of the 20th century.
The equation is derived by solving a linearized version of the Navier–Stokes equation for the perturbation velocity field
u=\left(U(z)+u'(x,z,t),0,w'(x,z,t)\right)
where
(U(z),0,0)
u'\propto\exp(i\alpha(x-ct))
| \mu | |
| i\alpha\rho |
\left({d2\overdz2}-\alpha2\right)2\varphi=(U-c)\left({d2\overdz2}-\alpha2\right)\varphi-U''\varphi
where
\mu
\rho
\varphi
\mu=0
U0
h
{1\overi\alphaRe}\left({d2\overdz2}-\alpha2\right)2\varphi=(U-c)\left({d2\overdz2}-\alpha2\right)\varphi-U''\varphi
where
| Re= | \rhoU0h |
| \mu |
is the Reynolds number of the base flow. The relevant boundary conditions are the no-slip boundary conditions at the channel top and bottom
z=z1
z=z2
\alpha\varphi={d\varphi\overdz}=0
z=z1
z=z2,
\varphi
Or:
\alpha\varphi={d\varphi\overdx}=0
z=z1
z=z2,
\varphi
The eigenvalue parameter of the problem is
c
\varphi
c
The equation can also be derived for three-dimensional disturbances of the form
u=\left(U(z)+u'(x,y,z,t),v'(x,y,z,t),w'(x,y,z,t)\right)
with
u'\propto\exp(i\alpha(x-ct)+i\betat)
For all but the simplest of velocity profiles
U
For plane Poiseuille flow, it has been shown that the flow is unstable (i.e. one or more eigenvalues
c
\alpha
Re>Rec=5772.22
Re=Rec
\alphac=1.02056
cr=0.264002
Im(\alpha{c})
\alpha
The first figure shows the spectrum of the Orr–Sommerfeld equation at the critical values listed above. This is a plot of the eigenvalues (in the form
λ=-i\alpha{c}
(Re,\alpha)
On the other hand, the spectrum of eigenvalues for Couette flow indicates stability, at all Reynolds numbers.[3] However, in experiments, Couette flow is found to be unstable to small, but finite, perturbations for which the linear theory, and the Orr–Sommerfeld equation do not apply. It has been argued that the non-normality of the eigenvalue problem associated with Couette (and indeed, Poiseuille) flow might explain that observed instability.[4] That is, the eigenfunctions of the Orr–Sommerfeld operator are complete but non-orthogonal. Then, the energy of the disturbance contains contributions from all eigenfunctions of the Orr–Sommerfeld equation. Even if the energy associated with each eigenvalue considered separately is decaying exponentially in time (as predicted by the Orr–Sommerfeld analysis for the Couette flow), the cross terms arising from the non-orthogonality of the eigenvalues can increase transiently. Thus, the total energy increases transiently (before tending asymptotically to zero). The argument is that if the magnitude of this transient growth is sufficiently large, it destabilizes the laminar flow, however this argument has not been universally accepted.[5]
A nonlinear theory explaining transition,[6] [7] has also been proposed. Although that theory does include linear transient growth, the focus is on 3D nonlinear processes that are strongly suspected to underlie transition to turbulence in shear flows. The theory has led to the construction of so-called complete 3D steady states, traveling waves and time-periodic solutions of the Navier-Stokes equations that capture many of the key features of transition and coherent structures observed in the near wall region of turbulent shear flows.[8] [9] [10] [11] [12] [13] Even though "solution" usually implies the existence of an analytical result, it is common practice in fluid mechanics to refer to numerical results as "solutions" - regardless of whether the approximated solutions satisfy the Navier-Stokes equations in a mathematically satisfactory way or not. It is postulated that transition to turbulence involves the dynamic state of the fluid evolving from one solution to the next. The theory is thus predicated upon the actual existence of such solutions (many of which have yet to be observed in a physical experimental setup). This relaxation on the requirement of exact solutions allows a great deal of flexibility, since exact solutions are extremely difficult to obtain (contrary to numerical solutions), at the expense of rigor and (possibly) correctness. Thus, even though not as rigorous as previous approaches to transition, it has gained immense popularity.
An extension of the Orr–Sommerfeld equation to the flow in porous media has been recently suggested.[14]
For Couette flow, it is possible to make mathematical progress in the solution of the Orr–Sommerfeld equation. In this section, a demonstration of this method is given for the case of free-surface flow, that is, when the upper lid of the channel is replaced by a free surface. Note first of all that it is necessary to modify upper boundary conditions to take account of the free surface. In non-dimensional form, these conditions now read
\varphi={d\varphi\overdz}=0,
z=0
| d2\varphi | |
| dz2 |
+\alpha2\varphi=0
| \Omega\equiv | d3\varphi |
| dz3 |
+i\alpha
| Re\left[\left(c-U\left(z | ||||
|
+\varphi\right]-i\alphaRe\left(
| 1 | + | |
| Fr |
| \alpha2 | \right) | |
| We |
| \varphi | |
| c-U\left(z2=1\right) |
=0,
z=1
The first free-surface condition is the statement of continuity of tangential stress, while the second condition relates the normal stress to the surface tension. Here
| Fr= |
| , We= | ||||||
| gh |
| |||||||||
| \sigma |
are the Froude and Weber numbers respectively.
For Couette flow
U\left(z\right)=z
\chi1\left(z\right)=\sinh\left(\alphaz\right), \chi2\left(z\right)=\cosh\left(\alphaz\right)
| \chi | ||||
|
| z\sinh\left[\alpha\left(z-\xi\right)\right]Ai\left[e | |
| \int | |
| infty |
i\pi/6\left(\alphaRe\right)1/3\left(\xi-c-
| i\alpha | |
| Re |
\right)\right]d\xi,
| \chi | ||||
|
| z\sinh\left[\alpha\left(z-\xi\right)\right]Ai\left[e | |
| \int | |
| infty |
5i\pi/6\left(\alphaRe\right)1/3\left(\xi-c-
| i\alpha | |
| Re |
\right)\right]d\xi,
where
Ai\left( ⋅ \right)
| 4 | |
| \varphi=\sum | |
| i=1 |
ci\chii\left(z\right)
ci
\left|\begin{array}{cccc}\chi1\left(0\right)&\chi2\left(0\right)&\chi3\left(0\right)&\chi4\left(0\right)\\ \chi1'\left(0\right)&\chi2'\left(0\right)&\chi3'\left(0\right)&\chi4'\left(0\right)\\ \Omega1\left(1\right)&\Omega2\left(1\right)&\Omega3\left(1\right)&\Omega4\left(1\right)\\ \chi
| 2\chi | |
| 1\left(1\right)&\chi |
| 2\chi | |
| 2\left(1\right)&\chi |
| 2\chi | |
| 3\left(1\right)&\chi |
| 2\chi | |
| 4\left(1\right)\end{array}\right|=0 |
must be satisfied. This is a single equation in the unknown c, which can be solved numerically or by asymptotic methods. It can be shown that for a range of wavenumbers
\alpha
\alphaci