Landau–Squire jet explained

In fluid dynamics, Landau–Squire jet or Submerged Landau jet describes a round submerged jet issued from a point source of momentum into an infinite fluid medium of the same kind. This is an exact solution to the incompressible form of the Navier-Stokes equations, which was first discovered by Lev Landau in 1944^[1] ^[2] and later by Herbert Squire in 1951.^[3] The self-similar equation was in fact first derived by N. A. Slezkin in 1934,^[4] but never applied to the jet. Following Landau's work, V. I. Yatseyev obtained the general solution of the equation in 1950.^[5] In the presence of solid walls, the problem is described by the Schneider flow.

Mathematical description

(r,\theta,\phi)

with velocity components

(u,v,0)

. The flow is axisymmetric, i.e., independent of

\phi

. Then the continuity equation and the incompressible Navier–Stokes equations reduce to

\begin{align} &

	1
	r²

	\partial
	\partialr

(r^2u)+

	1
	r\sin\theta

	\partial
	\partial\theta

(v\sin\theta)=0\\[8pt] &u

	\partialu
	\partialr

	v
	r

	\partialu
	\partial\theta

	v²
	r

	1
	\rho

	\partialp
	\partialr

+\nu\left(\nabla²u-

	2u
	r²

	2
	r²

	\partialv
	\partial\theta

	2v\cot\theta
	r²

\right)\\[8pt] &u

	\partialv
	\partialr

	v
	r

	\partialv
	\partial\theta

	uv
	r

	1
	\rhor

	\partialp
	\partial\theta

+\nu\left(\nabla²v+

	2
	r²

	\partialu
	\partial\theta

	v
	r^2\sin^2\theta

\right) \end{align}

where

\nabla²=

	1
	r²

	\partial
	\partialr

\left(r²

	\partial
	\partialr

\right)+

	1
	r^2\sin\theta

	\partial	\left(\sin\theta
	\partial\theta

	\partial
	\partial\theta

\right).

A self-similar description is available for the solution in the following form,^[6]

	\nu
	r\sin\theta

f'(\theta), v=-

	\nu
	r\sin\theta

f(\theta).

Substituting the above self-similar form into the governing equations and using the boundary conditions

u=v=p-p_infty=0

at infinity, one finds the form for pressure as

	p-p_infty
	\rho

	v²
	2

	\nuu
	r

	c₁
	r²

where

c₁

is a constant. Using this pressure, we find again from the momentum equation,

-	u²
	r

	v
	r

	\partialu
	\partial\theta

	\nu
	r²

\left[2u+

	1
	\sin\theta

	\partial	\left(\sin\theta
	\partial\theta

	\partialu
	\partial\theta

\right)\right]+

	2c₁
	r³

Replacing

\theta

\mu=\cos\theta

as independent variable, the velocities become

u=-

	\nu
	r

f'(\mu), v=-

	\nu
	r

	f(\mu)
	\sqrt{1-\mu²

}

(for brevity, the same symbol is used for

f(\theta)

and

f(\mu)

even though they are functionally the same, but takes different numerical values) and the equation becomes

f'²+ff''=2f'+[(1-\mu^2)f'']'-2c_1.

After two integrations, the equation reduces to

f²=4\muf+2(1-\mu²⁾f'-

	2
2(c
	1\mu

+c₂\mu+c_3),

where

c₂

and

c₃

are constants of integration. The above equation is a Riccati equation. After some calculation, the general solution can be shown to be

f=\alpha(1+\mu)+\beta(1-\mu)+

	2(1-\mu^2)(1+\mu)^\beta
	(1-\mu)^\alpha

\left[c-

	\mu
\int
	1

	(1+\mu)^\beta
	(1-\mu)^\alpha

\right]^-1,

where

\alpha, \beta, c

are constants. The physically relevant solution to the jet corresponds to the case

\alpha=\beta=0

(Equivalently, we say that

c_1=c_2=c₃₌₀

, so that the solution is free from singularities on the axis of symmetry, except at the origin).^[7] Therefore,

	2(1-\mu²⁾
	c+1-\mu

	2\sin^2\theta
	c+1-\cos\theta

The function

is related to the stream function as

\psi=\nurf

, thus contours of

for different values of

provides the streamlines. The constant

describes the force at the origin acting in the direction of the jet (this force is equal to the rate of momentum transfer across any sphere around the origin plus the force in the jet direction exerted by the sphere due to pressure and viscous forces), the exact relation between the force and the constant is given by

	F
	2\pi\rho\nu²

	32(c+1)
	3c(c+2)

+8(c+1)-4(c+1)^2ln

	c+2
	c

The solution describes a jet of fluid moving away from the origin rapidly and entraining the slowly moving fluid outside of the jet. The edge of the jet can be defined as the location where the streamlines are at minimum distance from the axis, i.e., the edge is given by

\theta_o=\cos^-1\left(

	1
	1+c

\right).

Therefore, the force can be expressed alternatively using this semi-angle of the conical-boundary of the jet,

	F
	2\pi\rho\nu²

	32
	3

\cos\theta_o

	2\theta
\sin
	o

	4
	\cos\theta_o

	1-\cos\theta_o
	1+\cos\theta_o

	8
	\cos\theta_o

Limiting behaviors

When the force becomes large, the semi-angle of the jet becomes small, in which case,

	F
	2\pi\rho\nu²

\sim

	2
3\theta
	o

\ll1

and the solution inside and outside of the jet become

\begin{align} f(\theta)&\sim

4\theta²

	2
\theta
	o

, \theta<\theta_o,\\f(\theta)&\sim2(1+\cos\theta), \theta>\theta_{o.
\end{align}}

The jet in this limiting case is called the Schlichting jet. On the other extreme, when the force is small,

	F
	2\pi\rho\nu²

\sim

	8
	c

\gg1

the semi-angle approaches 90 degree (no inside and outside region, the whole domain is considered as single region), the solution itself goes to

f(\theta)\sim	2
	c

\sin^2\theta.

Notes and References

Landau, L. D. (1944). New exact solution of the Navier-Stokes equations. In Doklady Akademii Nauk SSSR (Vol. 44, pp. 311-314).
Ter Haar, Dirk, ed. Collected papers of LD Landau. Elsevier, 2013.
Squire, H. B. (1951). The round laminar jet. The Quarterly Journal of Mechanics and Applied Mathematics, 4(3), 321-329.
Slezkin, N. A. "On an exact solution of the equations of viscous flow, Uch. zap." (1934): 89-90.
Yatseyev, V. I. (1950). About a class of exact solutions of viscous fluid equations of motion. Zhurnal Tekhnicheskoj Fiziki, 20(11), 1031-1034.
Sedov, L. I. (1993). Similarity and dimensional methods in mechanics. CRC press.
Batchelor, G. K. (2000). An introduction to fluid dynamics. Cambridge university press.

Landau–Squire jet explained

Mathematical description

Limiting behaviors

See also

Notes and References