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The steady flow of a weakly ionized gas between parallel plates assuming anisotropic conductivity
TBE STEADY FLOJVOF A WEAKLY IONIZED GAS
BETWEEN PARALLEL PLATES ASSUMING ANISOTROPIC CONDUCTIVXTY (USTANOVIVSEEESIA TECBENIE SLAB0 IONIZOVANNOGO HEZBDU PABALLELNYMI PLASTINAHI S UCEETOM ANISOTBOPII PBOVODIMOSTI) PYM
Vo1.25,
No.3,
I.
(Received
1961,
pp.
GAZA
473-477
B. CHEKMAREV (Leningrad) March
4,
1961)
It is well known that if the condition WT << 1 is not fulfilled in an ionized gas (where w is the cyclotron frequency of a charged particle and r is the average time between collisions (strong magnetic field, rarefied medium)), it is essential to take account of the fact that the transfer coefficients depend on the magnetic field, and they become anisotropic [I, 5-9 I, In the last few years several publications have appeared dealing with the flow of ionized gas, assuming anisotropic coefficients of viscosity and conductivity. Articles [ 2.3 1 give derivations of the fundamental magnetic plasmo-dynamic equations taking into account the influence of the magnetic field on the transfer process within a fully ionized gas, and a detailed study of Couette flow is adduced. Kaplan [ 4 I and Lighthill [ 11 1 have studied the effect of anisotropic conductivity on a magneto-gasdynamic shock wave and on the wave motion of a conducting medium. Article [lo 1 dealt with the effect of anisotropic conductivity on the longitudinal flow of a weakly ionized gas in a narrow annular channel within a radial magnetic field. This paper deals with steady flow of a weakly ionized gas between parallel non-conducting plates within a transverse homogeneous magnetic field B,. ‘Ihe following assumptions are made in order to simplify the problem: 1) the mean free path in the gas, X, is much less than the transverse dimension of the channel 2a, i.e. the conditions of a homogeneous medium are fulfilled;
2)the
degree of ionization of the gas is small;
3) the condition
OiTi << 1 is fulfilled for the ions, and this allows
701
I. B.
702
Chekmarev
the viscositycoefficientq to be considereda scalar quantity,and the effect of ion slip with respectto the gas can be neglected; 4) the followinginequalityis satisfied:R,.= up V,a << 1, where V, is the mean gas velocity in the channel; conditions allow one to use a stream function in the following j+wt(jxk)=o(E+vxB) (where k Is the unit vector 5) the physical constant.
i in the direction
characteristics
With these assumptions take the form
(21, (3) form:
or = Boez me ) of the magnetic
rotE = 0,
field)
of the gas (p, q, o, p, ~1 are assumed
the fundamental equations
~(vv)~=-v~+jxB+qAv, rot H = j, div H = 0,
and (4)
for
divv=O j+~~(jx~)~~(E+vxB) diwaB==@
this
problem
(1) (2) (3?
We will assume that the homogeneous external magnetic field B, = pHO whilst there are constant pressure gradients is parallel to the z-axis, along the x- and y-axes (~p/~x) = - P,, (dpfay) = - Pr and there is an external homogeneous electric field E, and Eay. All equations of the system (1) to (3) can then be satisfie d if we assume that the required quantities are functions of the transverse coordinate z only. The system therefore reduces to the following equations:
Flov
of a veakly
ionized
703
gas
Using (9) to eliminate the stream density from (41, we arrive components: following system of equations for the velocity
- ~-~2(Eov_l-OTEox) 11
@U --$L+os+= dz" d2v --dz2
N2 a~ D-cmY
(IO)
~u=-;+f2(E,,-orE,,) N2 =
The solution is of the form
of
Iv2
(11)
1 + WV
which is even with respect
(lo),
at the
to the z-coordinate,
u=
(12) aNz PNz + Clsiha* C‘psb - a cos a
V=-
sin aPNZ + il,
a
(13)
where zc:- -+1/~1+aW+1
p =
9
A, =
the constants
+ &2--
1/p?
A, = +&
9
If we determine
-&
(PV -
mP,)
1
(14)
-E%
(15)
Cr and C2 using the boundary conditions
u=v=o
for z=a
(1fi)
we find C = _ AlcosbaNcos PN + 1
c,
ApinhaN
A1 =
-
AlsinhaN
sin PN
9
sin PN - A.pxhctN cos PN . AI
A, = aidbz &V +
For volume. gas fluxes Qz and Q, in the directions axes, we obtain by calculation
Qx=
where
COST BN
(17)
of the x- and y-
i u&=2(1 (A, - "1":1:ay
CD1= asinbaM~~haN _t p sin pN cos PN (D2 = /3sfiaNc0shaN -
a sin
f3iV
co.5PN
(19)
I.B.
704
By
full
Cheknarev
use of Formula (9) we derive the following flows in the directions x and y:
expressions
for
the
--a
and u(z), by using (5) and (9), H, and Hy can be found. The in-
For known velocity components u(z) the induced magnetic-field intensities duced electric-field strength E, and the volumetric charge density 6 are determined from Equation (7). We now deal with two particular cases.
1) Assume that a given constant channel pressure gradient Pz along the x-axis maintains the steady motion Fig. 1. of the gas, whilst Q, = I,.= Eix = 0. ‘Ihis example corresponds to the problem of the flow of a conducting gas through an infinitely long channel with non-conducting walls whose width is large compared to the height. The conditions Q, = I, = 0 yield the equation -
‘%a + ‘ml MA 1
*‘-
It follows
from these
From system (21),
A
where
1
=
latter
using
_ o
expressions
(151,
B,$
that I,=
=0
(21)
0.
we find
MA, CM&-- @I) Pxa2 N2Az
A’2 = 01 (MA, -
Tbe flow in the x-axis
E,,-
,
direction
9
,4
=
2
’
MU’,2
pxa2
(22)
TV&--y-
CD,) f cD,(MA,oz
-
(Dz)
(23)
is given by the formula
QX = (MAI -Nf;\‘: +
a2.J
2p;n3
which for the case M = const, or + 0 leads to the well-known of the Hartmann problem with isotropic conductivity and total
(24) solution current
Flov of a veakly
ionized
705
gas
equal to zero: (25)
The graphs in Fig. 2 illustrate the relation between the flow OT given by Formula (24) for Q,” = QJ( 2P$ : q) and the quantity various values of the Hartmann number M, If only the intensity of the external magnetic field Ho is varied, the quantity y = ws/M remains
i%.
Fig.
2.
3.
constant and is a characteristic of the degree of rarefaction of the medium. A graph showing the relation between the flow Q,” and the Hartmann number is shown in Fig. 3. Daspite the fact that the total flow Qy and total current 1, are zero, because of the anisotropic character of the conductivity transverse flows and electric currents arise. 2) In the second example it is assumed that both the medium and the currents can flow freely in the x- and y-directions. For simplicity, put P = E,, = Eaz = 0, whilst the value of P, is assumed to be given. We t x en find
Qx=-
2P,a3(MA2 - @i) + ot@z Y*Al
’
I,=-I,=
--
2P,a mz & M& =xa Bo
MA1 MAI
tD1
(27)
1.B.
706
Cheksarev
or + 0, the expressions found transIn the limiting case M= const, form into formulas of another regime of motion in the Hartmann problem, in which the intensity of the electric field is equal to zero: QX _ zp;a’
Md$--
M
,
I, = _ T
““;~,;;~~~
(28).
A graph showing the ratio between the flow Q, arising because of anisotrogic conductivity of the transverse stream and the main flow Q, as a function of OT is shown in Fig. 4. Lateral and for
flow vanishes both when or + 0 large values of WT.
It follows from the illustrations on the graphs and from analysis of the formulas that at large values of or the solutions obtained tend asymptotically to the normal ones which correspond to the problem for a non-conducting fluid:
Thus the effect of a magnetic field on the main stream is weakened as the value of or increases because of the decrease in conductivity of the gas. On the other hand, anisotropic conductivity complicates the whole flow pattern, and this is expressed by the appearance of transverse flows, an induced electric field, and a volumetric electric charge.
Fig. 4.
BIBLIOGRAPHY magnitnogo polia na 1. Her&man, B.N. and Ginsburg, V.L., 0 vliianii konvektivnuiu neustoichivost’ v atmosferakh zvezd i v zemnoi ionosfere (The effect of a magnetic field on the convection-instability in the atmospheres of stars and in the terrestrial ionosphere). Astronor. Zh. Vol. 32, NO. 3, p. 201, 1955. 2.
Gubanov, A.I. and LWkin, Iu.P., Uravneniia magnitnoi plasmodinamiki (Magnetic equations of plasma dynamics). Zh. Tekh. Fiz. Vol. 30. No. 9, p. 1046, 1960.
Flow
of
a weakly
ionized
707
gas
3.
techenie v magnitnoi Gubanov, A. I. and Lun’ kin, IU. P. , Kuettovskoe plasmodinamike (Couette flow in magnetic plasma dynamics). Zh. Tekh. Fiz. Vol. 30. NO. 9. p. 1053, 1960.
4.
anizotropii provodimosti v magnitnom pole na Kaplan, S. A. , Vliianie strukturu udarnoi volny v magnitnoi gazodinamike ( The effect of anisotropic conductivity in a magnetic field on shock-wave structure in magnetic gasdynamics). Zh. eksp. teor. fiz. Vol. 38, No. 1, p. 252, 1960.
5.
KaUling,
T. , Magnitnaia
gidrodinanika
IIL.
(Magnetohydrodynanics).
1959.
obzor magnitnoi gidroA.R. and Petchek, G.E., Vvodnuii (Introductory review of magnetohydrodynamics). In Sb, “Magnitnaia gidrodinanika” (Collection ‘Magnetohydrodynamics”). Atomizdat. 1958.
6.
Kantrovits, dinamiki
7.
Landau.
L.D.
and Lifshitz,
(Electrodynamics
8.
9.
of
E.M.,
Continuous
Petchek, G. E., Aerodinamicheskaia sipation). In Sb.“Kosricheskaia Casdynari cs” ) . IIL, 1960. Spitser,
L.,
Completely
Fizika
polnost’in
Ionized
Gas).
Elektrodinarika Media).
dissipatsiia gazodinamika”
ionizouannogo
IIL,
sploshnykh
Gostekhizdat,
sred
1957.
(Aerodynamic (Collection
gaza
(The
dis‘Cosmic
Physics
of
1957.
anisotropii provodimosti na statsionarnoe 10. Chekmarev, I. B., Vliianie techenie neszhimaemogo viazkogo ionizovannogo gaza mezhdu koaksial’Wmi tsilindrami pri nalichii radial’nogo magnitnogo polia (The effect of anisotropic conductivity on the steady flow of incompressible, viscous, ionized gas between coaxial cylinders under the influence of a radial magnetic field). Lening. Polytekhn. Inst. i/r M.I. Ralinina. nauchnotekh. inform biull. No. 7. Section on Phys. and Mathem. Sciences. p. 81. 1960. 11.
Lighthill,
M. J.,
anisotropic 1014.
Studies on magnetohydrodynamic wave motions. Phil. Trans. Roy.
waves Sot.
and other
London
A252,
No.
1960.
Translated
by
V.H.B.
BETWEEN PARALLEL PLATES ASSUMING ANISOTROPIC CONDUCTIVXTY (USTANOVIVSEEESIA TECBENIE SLAB0 IONIZOVANNOGO HEZBDU PABALLELNYMI PLASTINAHI S UCEETOM ANISOTBOPII PBOVODIMOSTI) PYM
Vo1.25,
No.3,
I.
(Received
1961,
pp.
GAZA
473-477
B. CHEKMAREV (Leningrad) March
4,
1961)
It is well known that if the condition WT << 1 is not fulfilled in an ionized gas (where w is the cyclotron frequency of a charged particle and r is the average time between collisions (strong magnetic field, rarefied medium)), it is essential to take account of the fact that the transfer coefficients depend on the magnetic field, and they become anisotropic [I, 5-9 I, In the last few years several publications have appeared dealing with the flow of ionized gas, assuming anisotropic coefficients of viscosity and conductivity. Articles [ 2.3 1 give derivations of the fundamental magnetic plasmo-dynamic equations taking into account the influence of the magnetic field on the transfer process within a fully ionized gas, and a detailed study of Couette flow is adduced. Kaplan [ 4 I and Lighthill [ 11 1 have studied the effect of anisotropic conductivity on a magneto-gasdynamic shock wave and on the wave motion of a conducting medium. Article [lo 1 dealt with the effect of anisotropic conductivity on the longitudinal flow of a weakly ionized gas in a narrow annular channel within a radial magnetic field. This paper deals with steady flow of a weakly ionized gas between parallel non-conducting plates within a transverse homogeneous magnetic field B,. ‘Ihe following assumptions are made in order to simplify the problem: 1) the mean free path in the gas, X, is much less than the transverse dimension of the channel 2a, i.e. the conditions of a homogeneous medium are fulfilled;
2)the
degree of ionization of the gas is small;
3) the condition
OiTi << 1 is fulfilled for the ions, and this allows
701
I. B.
702
Chekmarev
the viscositycoefficientq to be considereda scalar quantity,and the effect of ion slip with respectto the gas can be neglected; 4) the followinginequalityis satisfied:R,.= up V,a << 1, where V, is the mean gas velocity in the channel; conditions allow one to use a stream function in the following j+wt(jxk)=o(E+vxB) (where k Is the unit vector 5) the physical constant.
i in the direction
characteristics
With these assumptions take the form
(21, (3) form:
or = Boez me ) of the magnetic
rotE = 0,
field)
of the gas (p, q, o, p, ~1 are assumed
the fundamental equations
~(vv)~=-v~+jxB+qAv, rot H = j, div H = 0,
and (4)
for
divv=O j+~~(jx~)~~(E+vxB) diwaB==@
this
problem
(1) (2) (3?
We will assume that the homogeneous external magnetic field B, = pHO whilst there are constant pressure gradients is parallel to the z-axis, along the x- and y-axes (~p/~x) = - P,, (dpfay) = - Pr and there is an external homogeneous electric field E, and Eay. All equations of the system (1) to (3) can then be satisfie d if we assume that the required quantities are functions of the transverse coordinate z only. The system therefore reduces to the following equations:
Flov
of a veakly
ionized
703
gas
Using (9) to eliminate the stream density from (41, we arrive components: following system of equations for the velocity
- ~-~2(Eov_l-OTEox) 11
@U --$L+os+= dz" d2v --dz2
N2 a~ D-cmY
(IO)
~u=-;+f2(E,,-orE,,) N2 =
The solution is of the form
of
Iv2
(11)
1 + WV
which is even with respect
(lo),
at the
to the z-coordinate,
u=
(12) aNz PNz + Clsiha* C‘psb - a cos a
V=-
sin aPNZ + il,
a
(13)
where zc:- -+1/~1+aW+1
p =
9
A, =
the constants
+ &2--
1/p?
A, = +&
9
If we determine
-&
(PV -
mP,)
1
(14)
-E%
(15)
Cr and C2 using the boundary conditions
u=v=o
for z=a
(1fi)
we find C = _ AlcosbaNcos PN + 1
c,
ApinhaN
A1 =
-
AlsinhaN
sin PN
9
sin PN - A.pxhctN cos PN . AI
A, = aidbz &V +
For volume. gas fluxes Qz and Q, in the directions axes, we obtain by calculation
Qx=
where
COST BN
(17)
of the x- and y-
i u&=2(1 (A, - "1":1:ay
CD1= asinbaM~~haN _t p sin pN cos PN (D2 = /3sfiaNc0shaN -
a sin
f3iV
co.5PN
(19)
I.B.
704
By
full
Cheknarev
use of Formula (9) we derive the following flows in the directions x and y:
expressions
for
the
--a
and u(z), by using (5) and (9), H, and Hy can be found. The in-
For known velocity components u(z) the induced magnetic-field intensities duced electric-field strength E, and the volumetric charge density 6 are determined from Equation (7). We now deal with two particular cases.
1) Assume that a given constant channel pressure gradient Pz along the x-axis maintains the steady motion Fig. 1. of the gas, whilst Q, = I,.= Eix = 0. ‘Ihis example corresponds to the problem of the flow of a conducting gas through an infinitely long channel with non-conducting walls whose width is large compared to the height. The conditions Q, = I, = 0 yield the equation -
‘%a + ‘ml MA 1
*‘-
It follows
from these
From system (21),
A
where
1
=
latter
using
_ o
expressions
(151,
B,$
that I,=
=0
(21)
0.
we find
MA, CM&-- @I) Pxa2 N2Az
A’2 = 01 (MA, -
Tbe flow in the x-axis
E,,-
,
direction
9
,4
=
2
’
MU’,2
pxa2
(22)
TV&--y-
CD,) f cD,(MA,oz
-
(Dz)
(23)
is given by the formula
QX = (MAI -Nf;\‘: +
a2.J
2p;n3
which for the case M = const, or + 0 leads to the well-known of the Hartmann problem with isotropic conductivity and total
(24) solution current
Flov of a veakly
ionized
705
gas
equal to zero: (25)
The graphs in Fig. 2 illustrate the relation between the flow OT given by Formula (24) for Q,” = QJ( 2P$ : q) and the quantity various values of the Hartmann number M, If only the intensity of the external magnetic field Ho is varied, the quantity y = ws/M remains
i%.
Fig.
2.
3.
constant and is a characteristic of the degree of rarefaction of the medium. A graph showing the relation between the flow Q,” and the Hartmann number is shown in Fig. 3. Daspite the fact that the total flow Qy and total current 1, are zero, because of the anisotropic character of the conductivity transverse flows and electric currents arise. 2) In the second example it is assumed that both the medium and the currents can flow freely in the x- and y-directions. For simplicity, put P = E,, = Eaz = 0, whilst the value of P, is assumed to be given. We t x en find
Qx=-
2P,a3(MA2 - @i) + ot@z Y*Al
’
I,=-I,=
--
2P,a mz & M& =xa Bo
MA1 MAI
tD1
(27)
1.B.
706
Cheksarev
or + 0, the expressions found transIn the limiting case M= const, form into formulas of another regime of motion in the Hartmann problem, in which the intensity of the electric field is equal to zero: QX _ zp;a’
Md$--
M
,
I, = _ T
““;~,;;~~~
(28).
A graph showing the ratio between the flow Q, arising because of anisotrogic conductivity of the transverse stream and the main flow Q, as a function of OT is shown in Fig. 4. Lateral and for
flow vanishes both when or + 0 large values of WT.
It follows from the illustrations on the graphs and from analysis of the formulas that at large values of or the solutions obtained tend asymptotically to the normal ones which correspond to the problem for a non-conducting fluid:
Thus the effect of a magnetic field on the main stream is weakened as the value of or increases because of the decrease in conductivity of the gas. On the other hand, anisotropic conductivity complicates the whole flow pattern, and this is expressed by the appearance of transverse flows, an induced electric field, and a volumetric electric charge.
Fig. 4.
BIBLIOGRAPHY magnitnogo polia na 1. Her&man, B.N. and Ginsburg, V.L., 0 vliianii konvektivnuiu neustoichivost’ v atmosferakh zvezd i v zemnoi ionosfere (The effect of a magnetic field on the convection-instability in the atmospheres of stars and in the terrestrial ionosphere). Astronor. Zh. Vol. 32, NO. 3, p. 201, 1955. 2.
Gubanov, A.I. and LWkin, Iu.P., Uravneniia magnitnoi plasmodinamiki (Magnetic equations of plasma dynamics). Zh. Tekh. Fiz. Vol. 30. No. 9, p. 1046, 1960.
Flow
of
a weakly
ionized
707
gas
3.
techenie v magnitnoi Gubanov, A. I. and Lun’ kin, IU. P. , Kuettovskoe plasmodinamike (Couette flow in magnetic plasma dynamics). Zh. Tekh. Fiz. Vol. 30. NO. 9. p. 1053, 1960.
4.
anizotropii provodimosti v magnitnom pole na Kaplan, S. A. , Vliianie strukturu udarnoi volny v magnitnoi gazodinamike ( The effect of anisotropic conductivity in a magnetic field on shock-wave structure in magnetic gasdynamics). Zh. eksp. teor. fiz. Vol. 38, No. 1, p. 252, 1960.
5.
KaUling,
T. , Magnitnaia
gidrodinanika
IIL.
(Magnetohydrodynanics).
1959.
obzor magnitnoi gidroA.R. and Petchek, G.E., Vvodnuii (Introductory review of magnetohydrodynamics). In Sb, “Magnitnaia gidrodinanika” (Collection ‘Magnetohydrodynamics”). Atomizdat. 1958.
6.
Kantrovits, dinamiki
7.
Landau.
L.D.
and Lifshitz,
(Electrodynamics
8.
9.
of
E.M.,
Continuous
Petchek, G. E., Aerodinamicheskaia sipation). In Sb.“Kosricheskaia Casdynari cs” ) . IIL, 1960. Spitser,
L.,
Completely
Fizika
polnost’in
Ionized
Gas).
Elektrodinarika Media).
dissipatsiia gazodinamika”
ionizouannogo
IIL,
sploshnykh
Gostekhizdat,
sred
1957.
(Aerodynamic (Collection
gaza
(The
dis‘Cosmic
Physics
of
1957.
anisotropii provodimosti na statsionarnoe 10. Chekmarev, I. B., Vliianie techenie neszhimaemogo viazkogo ionizovannogo gaza mezhdu koaksial’Wmi tsilindrami pri nalichii radial’nogo magnitnogo polia (The effect of anisotropic conductivity on the steady flow of incompressible, viscous, ionized gas between coaxial cylinders under the influence of a radial magnetic field). Lening. Polytekhn. Inst. i/r M.I. Ralinina. nauchnotekh. inform biull. No. 7. Section on Phys. and Mathem. Sciences. p. 81. 1960. 11.
Lighthill,
M. J.,
anisotropic 1014.
Studies on magnetohydrodynamic wave motions. Phil. Trans. Roy.
waves Sot.
and other
London
A252,
No.
1960.
Translated
by
V.H.B.