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On the onset of convection in a water-saturated porous box: Effect of conducting walls
IN H E A T A S D M A S S T R A N S F E R 0094-4548/78/ii01-0371502.00/0 Vol. 5, pp. 371-378, 1978 © P e r g a m o n P r e s s Ltd. Printed in GreatBritain
ON THE ONSET OF CONVECTION IN A WATER-SATURATED POROUS BOX: EFFECT OF CONDUCTING WALLS *
Robert P. Lowell 1.
2.
1
and Chuen-Tien Shyu
2
School o f Geophysical Sciences, Georgia I n s t i t u t e o f Technology Atlanta, Georgia 30332 School of Oceanography, Oregon State University, Corvallis, Oregon 97331
(Communicated by J.P. Hartnett and W.J. M/nkowycz)
ABSTRACT The c r i t i c a l Rayleigh number f o r the onset o f convection in a w a t e r - s a t u r a t e d porous box, heated from below, has been d e t e r mined by the G a l e r k i n method and by an approximate a n a l y t i c a l technique. The present problem d i f f e r s from previous ones which have been published in t h a t we consider the e f f e c t o f conducting v e r t i c a l boundaries on the c r i t i c a l number and on the c e l l p a t t e r n at the c r i t i c a l number. Moreover, we emphasize f a u l t or f r a c t u r e z o n e - l i k e box geometries; t h a t is , geometries in which one box dimension is much s h o r t e r than the o t h e r and much s h o r t e r than the h e i g h t . The r e s u l t s i n d i c a t e that f o r f a u l t / f r a c t u r e zone geometries, in which the long v e r t i c a l w a l l s are conducting and the short end w a l l s are i n s u l a t e d , the c r i t i c a l Raylelgh number is roughly four orders o f magnitude g r e a t e r than the c r i t i c a l number f o r a h o r i z o n t a l porous slab. The f l o w at the onset o f convection takes the form o f a r o l l w i t h i t s axis along the long h o r i z o n t a l dimension o f the box. There i s , however, l i t t l e d i f f e r e n c e between the c r i t i c a l numbers f o r two and three dimensional c e l l p a t t e r n s . These r e u s l t s i n d i c a t e t h a t convection may occur in n a t u r a l l y o c c u r r i n g f a u l t s and f r a c t u r e zones in the e a r t h ' s crust o n l y i f the p e r m e a b i l i t y is of the order o f Darcies. In n a t u r a l systems, the Rayleigh number would probably not exceed the c r i t i c a l number g r e a t l y , and the f l o w may tend to be f u l l y three dimensional. *This manuscript is submitted for publication with the understanding that the United States Government is authorized to reproduce and distribute reprints for governmental purposes. 371
372
R.P. Lowell and C.-T. Shyu
Vol. 5, No. 6
Introduction The onset o f convection in a closed r e c t a n g u l a r c o n t a i n e r o f w a t e r s a t u ra t e d porous m a t e r i a l w i t h uniform p r o p e r t i e s has been t r e a t e d by Beck (1), and the case o f a v a r i a b l e v i s c o s i t y f l u i d Zebib and Kassoy (2).
has been t r e a t e d by
These authors have considered v ar ious box geometries,
but they have assumed t h a t the v e r t i c a l w a l l s o f the box are i n s u l a t e d . In many p r a c t i c a l s i t u a t i o n s , however, such as in geothermal systems c o n t r o l l e d by f a u l t and f r a c t u r e zones, the assumption o f i n s u l a t e d v e r t i c a l w a l l s is not r e a l i s t i c .
We wish to consider the e f f e c t o f
conducting w a l l s on the c r i t i c a l at the c r i t i c a l
Rayleigh number and on the c e l l p a t t e r n
Rayleigh number.
Moreover, we w i l l
f r a c t u r e c o n t r o l l e d geometry; t h a t i s , we w i l l
emphasize a f a u l t or
emphasize porous c o n t a i n e r
geometries in which one h o r i z o n t a l dimension is much s h o r t e r than the o t h e r and much s h o r t e r than the h e i g h t .
We w i l l
assume t h a t the long
w a l l s are conducting but t h a t the s h o r t , end- w alls are i n s u l a t e d . will
then discuss the p o s s i b i l i t y
f a u l t s or f r a c t u r e s
We
o f convection t a k i n g place in n a t u r a l
in the earthJs c r u s t .
Davis (3) and Catton (4) have t r e a t e d the s i m i l a r problem o f convection in a r e c t a n g u l a r c o n t a i n e r having conducting w a l l s and being filled
w i t h viscous f l u i d . Analysi.s Consider a c o n t a i n e r o f w a t e r - s a t u r a t e d porous m a t e r i a l o f h e i g h t L
and w i t h h o r i z o n t a l dimensions L 1 and L2.
Let a uniform thermal g r a d i e n t ,
, be a p p l i e d to the m a t e r i a l such t h a t the temperature at the upper surface is T = T (TO >Ts).
and the temperature at the lower surface is T = T s o The i n i t i a l s t a t e is assumed to be one o f pure thermal
conduction such t h a t i n i t i a l l y v = O, T = Ts +
Bz,
dP*/dz = Pfg
where ~ is the velocity, P* the pressure, Pf the density of the fluid and g the acceleration due to gravity.
The z axis assumed to be positive
downwards. The condition for the onset of convection is found by the principle of exchange of stabilities.
That is, infinitesimal perturbation of the
initial state leads to a marginally stable state of steady thermal convection.
The linearized, non-dimensional, marginal stability equations,
usina the Boussinesq anproximation are (5)
VOI. 5, NO. 6
~ I O N
I%.IA WAT~-SATURATED
P O E U S BOX
V.q : 0 + R½0k + VP : 0
373
(I) (2)
v20-R½qz = 0 (3) + where q = (qx,qy,qz) is the perturbation v e l o c i t y , 0 is the perturbation temperature, P is the perturbation pressure, and k is a u n i t vector in the z direction.
R is the dimensionless Rayleigh number given by R = pfs~SKgL2/vX
w h e r e s is t h e s p e c i f i c coefficient, k
its
ature
v its
thermal
heat of
kiematic
conductivity.
the fluid,
viscosity,
~ its
thermal expansion
K the permeability
These e q u a t i o n s
of
t h e r o c k and
a r e t o be s o l v e d w i t h
temper-
conditions, a e / a x = 0 a t x = 0,H 1 e = 0
(4) (S)
a t y = 0,H^
z
0,I z
where H I and H 2 are dimensionless horizontal
lengths.
Assuming impermeable
boundaries, the velocity conditions are .
n =
0
(6)
^
on a l l boundaries, where n is the unit vector, normal to the wall. Equations
(I) through (3) with conditions
(4) through (6) constitute an
eigenvalue problem for the Rayleigh parameter, the smallest eigenvalue being the critical Rayleigh number for the onset of convection. The set of equations and boundary conditions above are not separable, and consequently the normal solution procedures break down. One method of determining the critical Rayleigh number for problems of this type is the Galerkin method.
To use this method, we first eliminate
and P from the perturbation equations to obtain a single equation for e. We obta in V40 + R~Th20 = 0 where Vh2 is the horizontal Laplacian.
(7)
We then select a set of t r i a l
functions 0. which satisfy the temperature and the v e l o c i t y boundary J
conditions.
We substitute N
O=
Z
i=1
C.O. I
I
into (7) and apply the Galerkin c r i t e r i o n .
That is,
374
R.P. LOwell and C.-T. Shyu
Vol. 5, No. 6
N
! I C [ V2 (V20) + RVh2ei] .OkdV = 0
i I
i
(9)
i
where the integral (9) is carried out over the volume of the box, and 8 k, is one component of the set of trial functions
8.. I
Substitution of the
particular trial functions into (9) gives rise to a matrix equation of the form MAT = RMB~
(IO)
and the condition for a non-trivial solution is that the determinant of the coefficients be zero.
That is: MA -1M B - R -11
= 0
Equation (II) represents an eigenvalue problem for the Rayleigh number R; and the minimum eigenvalue found, R = Rc, represents the critical condition for the onset of convection.
The results for the critical
Rayleigh number, for different box geometries are given in Table I. TABLE I Critical Rayleigh Numbers 2-D and 3-D Convection in a Porous Box With Two Vertical Conducting Walls
H2~
2-D (i=O)
O.01
0.05 O.1
446831.6 17485.16 4327.77
HI~
3-D I
5
I0
446835.7
446832.1
446832.1
17488.8
17485.4
17485.3
4331.35
20
446832.1 17485.26
5O 446~32. I 17485.2
4327.92
4327 81
4327.75
4327.78
212.68
212.69
0.5
212.75
216.34
212.90
212 70
1.0
83.22
86.07
83.48
83 36
83.34
83.32
1.5
60.50
61.73
60.58
6O 52
60.50
60.50
40.66
40.66
3
43.57
40.85
40.86
4O 61
5
41.01
39.61
39.62
39 62
39.60
39.60
I0
39.87
39.48
39.48
39 49 39 48
39.49
39.49
39.48
39.48
5O
39.48
39.48
39.48
Vol. 5, NO. 6
CONVEC'gICN IN A ~ATER-SATURATED POROUS BOX
375
Discussion T a b l e 1 shows s e v e r a l with
interesting
two c o n d u c t i n g w a l l s .
dimensions,
the wall
First,
conditions
it
features of convection is c l e a r
if
the c o n d u c t i n g w a l l s
for
are far apart
f o r an i n f i n i t e
(H25 2 ) ,
between the i n s u l a t e d w a l l s
number
slab.
Secondly,
t h r e e d i m e n s i o n a l m o t i o n is
o v e r two d i m e n s i o n a l a t t h e o n s e t o f c o n v e c t i o n ;
separation
in a box
l a r g e box
become i m m a t e r i a l and t h e c r i t i c a l
approaches t h e v a ] u e 4 ~ 2 g i v e n by Lapwood (5)
preferred
that
increases
(HI+~),
and as t h e the three-
d i m e n s i o n a l v a l u e s o f R approaches t h e t w o - d i m e n s i o n a l v a l u e s . This c s u g g e s t s t h a t in n a t u r a l systems the m o t i o n s may tend t o be f u l l y t h r e e dimensional
rather
than r o l l - l i k e
suggest that at finite solutions
in c h a r a c t e r .
amplitude (i.e.,
Moreover, these results
R >R c) the
may be u n s t a b l e and t h e m o t i o n a t f i n i t e
three-dimenslonal.
Lastly,
two-dimensional a m p l i t u d e may become
in the case o f a f a u l t / f r a c t u r e
zone g e o m e t r y
(H 2 <<1, Hi 3 1 ) , T a b l e 1 shows t h a t Rc i s s e v e r a l o r d e r s o f m a g n i t u d e greater
than t h e v a l u e 4~ 2 f o r an i n f i n i t e
t a k e s t h e form o f a r o l l d i m e n s i o n o f t h e box. showed t h a t , para]lel
for
with This
its
axis parallel
is c o n t r a r y
insulated walls,
slab,
and t h e m o t i o n a t R = R c t o t h e long h o r i z o n t a l
t o the r e s u l t s
the r o l l s
their
axes
t o t h e s h o r t s i d e o f t h e box.
The r e s u l t s
in T a b l e 1 f o r a f a u l t / f r a c t u r e
zone geometry a r e in
r e a s o n a b l e agreement w i t h an a p p r o x i m a t e a n a l y t i c a l Lowell
(6).
velocity
The a n a l y t i c a l
calculations
boundary c o n d i t i o n s
condition
result
d e r i v e d by
were p e r f o r m e d by r e l a x i n g
on t h e v e r t i c a l
walls.
the
I f one r e p l a c e s the
qy= 0 a t y = O, H2 w i t h ~qz/~Z = 0 a t y = O, H2, t h e e i g e n f u n c t i o n s
become s e p a r a b l e , and e q u a t i o n this
o f Beck (1) who
were a l i g n e d w i t h
case, w i t h H 1 + ~ ,
(7) can be s o l v e d by s t a n d a r d methods.
H2<< 1, L o w e l l
In
(6) o b t a i n s :
R = 4~ 2 /H 2 c 2 With H2 = 0 . 0 1 ,
Rc
4 x 105
w h i c h is a b o u t ten p e r c e n t s m a l l e r than
t h e v a l u e found by t h e G a l e r k i n method. e x p e c t e d in v i e w o f the f a c t restrictive
in t h e a n a l y t i c a l
The a n a l y t i c a l a roll
with
its
results
that
T h i s u n d e r e s t i m a t e o f R i s t o be c the boundary c o n d i t i o n s were l e s s
calculations
a l s o show t h a t
axis along the strike Geophysical
T a b l e 1 shows t h a t material
with a fault
than in t h e G a l e r k i n method.
t h e f l o w a t R = R t a k e s p l a c e as c of the fault.
Implications
in a c l o s e d c o n t a i n e r o f w a t e r - s a t u r a t e d
or fracture
zone g e o m e t r y , e . g . ,
porous
w i t h H2 = 0 . 0 1 ,
the
376
R.P. ~ i i
and C.-T.
Shyu
critical
R a y l e i g h number is n e a r l y 4.5 x 10 5 .
possible
in n a t u r a l
and a f a u l t
systems?
5, No. 6
Are such h i g h R a y l e i g h numbers
Assuming a t e m p e r a t u r e g r a d i e n t
8 = iO0°C/km
d e p t h o f 3 km, which a r e r e a s o n a b l e f o r a g e o t h e r m a l r e g i o n ,
we e s t i m a t e v a l u e s o f the p h y s i c a l
p a r a m e t e r s from S t r a u s and S c h u b e r t ( 7 ) :
pfs = I cal/cm 3 - °C,~ = 1.5 x 10-3/°C,v -
Vol.
°C - s e c .
e,v,l
these parameters
are average
into the Rayleigh
onset of convection
not unrealistic
separation
for
fault zone.
the p e r m e a b i l i t y
fractures
within
due t o a s e r i e s o f f l a t h, Bear (8, p.
= 2 x 10-3cm/sec, ~ = 5 x 10-3cal/cm
over the depth
range.
Substituting
number gives K =3 x 10-8cm 2, for the
in a 50 m wide
value,
from i n t e r c o n n e c t e d permeability
values
This
is quite a high,
in a f a u l t
but
zone m a i n ] y a r i s e s
t h e r o c k volume; and assuming a parallel
fractures
o f w i d t h d and
164) has shown t h a t K = d3/12h
This,
if
on t h i s
K = 3 x IO-8cm 2, h = 100 cm, then d = 3.3 x I0-2cm. s c a l e do n o t appear u n r e a s o n a b l e f o r a f a u l t
the earth's
crust.
in such systems, critical
that
the a c t u a l
gradient
we emphasize t h a t
a l o n g the w a l l s
of convection in t i m e ,
R a y l e i g h number l i e s
zone in
convection occurs rather
close to the
the a s s u m p t i o n o f a u n i f o r m t h e r m a l
is o n l y a p p r o p r i a t e
in a n a t u r a l
the g r a d i e n t
be m a i n t a i n e d .
fault
or fracture
insulated
in the a d j a c e n t
In t i m e t h e r e w i l l
a c r o s s the w a i l s ,
as a c o n d i t i o n zone.
for
boundaries.
convection
f l o w may d e c l i n e
For t h i s
is
initiated.
As c o n v e c t i o n proceeds
be a d e c r e a s e in t h e l a t e r a l
porous c o n t a i n e r w i t h
and perhaps t o change i t s
cell
is reduced.
t i m e dependent a s p e c t s o f c o n v e c t i o n
in a
An e x a m i n a t i o n o f t h e s e p r o b l e m s
research.
r e s e a r c h was s u p p o r t e d by t h e U. S. G e o l o g i c a l Survey, Interior
In
may be somewhat more c o m p l i c a t e d
Acknowledgments
Department o f
pattern,
however, t h e c o n v e c t i v e
temperature gradient
insulated walls.
be a s u b j e c t o f f u t u r e
gradient
r e a s o n , one m i g h t e x p e c t c o n v e c t i o n
conducting walls
than in c o n t a i n e r s w i t h
not
tend t o have the appearance
At l a r g e t i m e s ,
s i n c e the d r i v i n g
summary, t h e f i n i t e - a m p l i t u d e ,
This
the o n s e t
impermeable r o c k m a t r i x w i l l
and hence the w a l l s w i l l
t o become somewhat more v i g o r o u s ,
will
if
a t v a l u e s o f R>Rc, and heat is conducted t h r o u g h the v e r t i c a l
boundaries,
after
or fracture
however, t h a t
number.
Finally,
of
One m i g h t e x p e c t ,
Fractures
under USGS Grant No.
14-O8-0001-G-365.
VOl. 5, ~b. 6
CONVECfION IN A ~TER-SATURATED POROUS BOX
Nomenclature C C° I
-
v e c t o r o f expansion c o e f f i c i e n t s o f t r i a l
solutions
component expansion c o e f f i c i e n t s o f t r i a l
solutions
d
fracture width
g
acceleration due to gravity
h
fracture separation
dimensionless horizontal box lengths hl,H 2 K permeability of rock -
k
unit vector in z direction
L
dimensional box height
LI,L 2 -
horizontal box dimensions
MA,MB h
matrices arising in Galerkin formulation
P
-
unit vector in z direction dimensionless perturbation pressure dimensional f l u i d pressure
+
q,qx,qy,qz-dimensionless perturbation velocity, components R
dimensionless Rayleigh number
R
critical
s
s p e c i f i c heat o f f l u i d
T
temperature
T o T
temperature at base o f box
C
Rayleigh number
ten~perature at surface
S
v
-
Darcy v e l o c i t y o f f l u i d
x,y,z
c a r t e s i a n c o o r d i n a t e s , z p o s i t i v e downwards
-
therma] expansion c o e f f i c i e n t
8
-
geothermal g r a d i e n t
0
-
dimensionless p e r t u r b a t i o n temperature
Oi,ek,X
and c a r t e s i a n
t r i a l temperature function in Galerkln formulation
-
thermal conductivity of saturated material
-
kinematic viscosity of f l u i d
pf -
f l u i d density
377
378
R.P. Lowell and C.-T. Shyu
Vol. 5, hb. 6
REFERENCES
I.
J. L. Beck, Phys. Fluids, 15, 1377 (1972).
2.
A. Zebib and D. R. Kassoy, Phys. Fluids, 20, 4 (1977).
3.
S. H. Davis, J. Fluid Mech. 3(3, 465 (1967).
4.
I. Catton, Jour. Heat Transfer,
5.
E. R. Lapwood, Proc. Cambridge Phil., Soc. 44, 508 (1948).
6.
R. P. Lowell, Semi-annual grant #14-08-0001-G-365,
9_.22,186 (1970).
technical
letter report no. I, USGS
10p (1977).
7.
J. M. Straus and G. Schubert, J. Geophys. Res., 82, 325 (1977).
8.
J. Bear, Dynamics of Fluids in Porous Media, Elsevier, New York, 764p (1972).
ON THE ONSET OF CONVECTION IN A WATER-SATURATED POROUS BOX: EFFECT OF CONDUCTING WALLS *
Robert P. Lowell 1.
2.
1
and Chuen-Tien Shyu
2
School o f Geophysical Sciences, Georgia I n s t i t u t e o f Technology Atlanta, Georgia 30332 School of Oceanography, Oregon State University, Corvallis, Oregon 97331
(Communicated by J.P. Hartnett and W.J. M/nkowycz)
ABSTRACT The c r i t i c a l Rayleigh number f o r the onset o f convection in a w a t e r - s a t u r a t e d porous box, heated from below, has been d e t e r mined by the G a l e r k i n method and by an approximate a n a l y t i c a l technique. The present problem d i f f e r s from previous ones which have been published in t h a t we consider the e f f e c t o f conducting v e r t i c a l boundaries on the c r i t i c a l number and on the c e l l p a t t e r n at the c r i t i c a l number. Moreover, we emphasize f a u l t or f r a c t u r e z o n e - l i k e box geometries; t h a t is , geometries in which one box dimension is much s h o r t e r than the o t h e r and much s h o r t e r than the h e i g h t . The r e s u l t s i n d i c a t e that f o r f a u l t / f r a c t u r e zone geometries, in which the long v e r t i c a l w a l l s are conducting and the short end w a l l s are i n s u l a t e d , the c r i t i c a l Raylelgh number is roughly four orders o f magnitude g r e a t e r than the c r i t i c a l number f o r a h o r i z o n t a l porous slab. The f l o w at the onset o f convection takes the form o f a r o l l w i t h i t s axis along the long h o r i z o n t a l dimension o f the box. There i s , however, l i t t l e d i f f e r e n c e between the c r i t i c a l numbers f o r two and three dimensional c e l l p a t t e r n s . These r e u s l t s i n d i c a t e t h a t convection may occur in n a t u r a l l y o c c u r r i n g f a u l t s and f r a c t u r e zones in the e a r t h ' s crust o n l y i f the p e r m e a b i l i t y is of the order o f Darcies. In n a t u r a l systems, the Rayleigh number would probably not exceed the c r i t i c a l number g r e a t l y , and the f l o w may tend to be f u l l y three dimensional. *This manuscript is submitted for publication with the understanding that the United States Government is authorized to reproduce and distribute reprints for governmental purposes. 371
372
R.P. Lowell and C.-T. Shyu
Vol. 5, No. 6
Introduction The onset o f convection in a closed r e c t a n g u l a r c o n t a i n e r o f w a t e r s a t u ra t e d porous m a t e r i a l w i t h uniform p r o p e r t i e s has been t r e a t e d by Beck (1), and the case o f a v a r i a b l e v i s c o s i t y f l u i d Zebib and Kassoy (2).
has been t r e a t e d by
These authors have considered v ar ious box geometries,
but they have assumed t h a t the v e r t i c a l w a l l s o f the box are i n s u l a t e d . In many p r a c t i c a l s i t u a t i o n s , however, such as in geothermal systems c o n t r o l l e d by f a u l t and f r a c t u r e zones, the assumption o f i n s u l a t e d v e r t i c a l w a l l s is not r e a l i s t i c .
We wish to consider the e f f e c t o f
conducting w a l l s on the c r i t i c a l at the c r i t i c a l
Rayleigh number and on the c e l l p a t t e r n
Rayleigh number.
Moreover, we w i l l
f r a c t u r e c o n t r o l l e d geometry; t h a t i s , we w i l l
emphasize a f a u l t or
emphasize porous c o n t a i n e r
geometries in which one h o r i z o n t a l dimension is much s h o r t e r than the o t h e r and much s h o r t e r than the h e i g h t .
We w i l l
assume t h a t the long
w a l l s are conducting but t h a t the s h o r t , end- w alls are i n s u l a t e d . will
then discuss the p o s s i b i l i t y
f a u l t s or f r a c t u r e s
We
o f convection t a k i n g place in n a t u r a l
in the earthJs c r u s t .
Davis (3) and Catton (4) have t r e a t e d the s i m i l a r problem o f convection in a r e c t a n g u l a r c o n t a i n e r having conducting w a l l s and being filled
w i t h viscous f l u i d . Analysi.s Consider a c o n t a i n e r o f w a t e r - s a t u r a t e d porous m a t e r i a l o f h e i g h t L
and w i t h h o r i z o n t a l dimensions L 1 and L2.
Let a uniform thermal g r a d i e n t ,
, be a p p l i e d to the m a t e r i a l such t h a t the temperature at the upper surface is T = T (TO >Ts).
and the temperature at the lower surface is T = T s o The i n i t i a l s t a t e is assumed to be one o f pure thermal
conduction such t h a t i n i t i a l l y v = O, T = Ts +
Bz,
dP*/dz = Pfg
where ~ is the velocity, P* the pressure, Pf the density of the fluid and g the acceleration due to gravity.
The z axis assumed to be positive
downwards. The condition for the onset of convection is found by the principle of exchange of stabilities.
That is, infinitesimal perturbation of the
initial state leads to a marginally stable state of steady thermal convection.
The linearized, non-dimensional, marginal stability equations,
usina the Boussinesq anproximation are (5)
VOI. 5, NO. 6
~ I O N
I%.IA WAT~-SATURATED
P O E U S BOX
V.q : 0 + R½0k + VP : 0
373
(I) (2)
v20-R½qz = 0 (3) + where q = (qx,qy,qz) is the perturbation v e l o c i t y , 0 is the perturbation temperature, P is the perturbation pressure, and k is a u n i t vector in the z direction.
R is the dimensionless Rayleigh number given by R = pfs~SKgL2/vX
w h e r e s is t h e s p e c i f i c coefficient, k
its
ature
v its
thermal
heat of
kiematic
conductivity.
the fluid,
viscosity,
~ its
thermal expansion
K the permeability
These e q u a t i o n s
of
t h e r o c k and
a r e t o be s o l v e d w i t h
temper-
conditions, a e / a x = 0 a t x = 0,H 1 e = 0
(4) (S)
a t y = 0,H^
z
0,I z
where H I and H 2 are dimensionless horizontal
lengths.
Assuming impermeable
boundaries, the velocity conditions are .
n =
0
(6)
^
on a l l boundaries, where n is the unit vector, normal to the wall. Equations
(I) through (3) with conditions
(4) through (6) constitute an
eigenvalue problem for the Rayleigh parameter, the smallest eigenvalue being the critical Rayleigh number for the onset of convection. The set of equations and boundary conditions above are not separable, and consequently the normal solution procedures break down. One method of determining the critical Rayleigh number for problems of this type is the Galerkin method.
To use this method, we first eliminate
and P from the perturbation equations to obtain a single equation for e. We obta in V40 + R~Th20 = 0 where Vh2 is the horizontal Laplacian.
(7)
We then select a set of t r i a l
functions 0. which satisfy the temperature and the v e l o c i t y boundary J
conditions.
We substitute N
O=
Z
i=1
C.O. I
I
into (7) and apply the Galerkin c r i t e r i o n .
That is,
374
R.P. LOwell and C.-T. Shyu
Vol. 5, No. 6
N
! I C [ V2 (V20) + RVh2ei] .OkdV = 0
i I
i
(9)
i
where the integral (9) is carried out over the volume of the box, and 8 k, is one component of the set of trial functions
8.. I
Substitution of the
particular trial functions into (9) gives rise to a matrix equation of the form MAT = RMB~
(IO)
and the condition for a non-trivial solution is that the determinant of the coefficients be zero.
That is: MA -1M B - R -11
= 0
Equation (II) represents an eigenvalue problem for the Rayleigh number R; and the minimum eigenvalue found, R = Rc, represents the critical condition for the onset of convection.
The results for the critical
Rayleigh number, for different box geometries are given in Table I. TABLE I Critical Rayleigh Numbers 2-D and 3-D Convection in a Porous Box With Two Vertical Conducting Walls
H2~
2-D (i=O)
O.01
0.05 O.1
446831.6 17485.16 4327.77
HI~
3-D I
5
I0
446835.7
446832.1
446832.1
17488.8
17485.4
17485.3
4331.35
20
446832.1 17485.26
5O 446~32. I 17485.2
4327.92
4327 81
4327.75
4327.78
212.68
212.69
0.5
212.75
216.34
212.90
212 70
1.0
83.22
86.07
83.48
83 36
83.34
83.32
1.5
60.50
61.73
60.58
6O 52
60.50
60.50
40.66
40.66
3
43.57
40.85
40.86
4O 61
5
41.01
39.61
39.62
39 62
39.60
39.60
I0
39.87
39.48
39.48
39 49 39 48
39.49
39.49
39.48
39.48
5O
39.48
39.48
39.48
Vol. 5, NO. 6
CONVEC'gICN IN A ~ATER-SATURATED POROUS BOX
375
Discussion T a b l e 1 shows s e v e r a l with
interesting
two c o n d u c t i n g w a l l s .
dimensions,
the wall
First,
conditions
it
features of convection is c l e a r
if
the c o n d u c t i n g w a l l s
for
are far apart
f o r an i n f i n i t e
(H25 2 ) ,
between the i n s u l a t e d w a l l s
number
slab.
Secondly,
t h r e e d i m e n s i o n a l m o t i o n is
o v e r two d i m e n s i o n a l a t t h e o n s e t o f c o n v e c t i o n ;
separation
in a box
l a r g e box
become i m m a t e r i a l and t h e c r i t i c a l
approaches t h e v a ] u e 4 ~ 2 g i v e n by Lapwood (5)
preferred
that
increases
(HI+~),
and as t h e the three-
d i m e n s i o n a l v a l u e s o f R approaches t h e t w o - d i m e n s i o n a l v a l u e s . This c s u g g e s t s t h a t in n a t u r a l systems the m o t i o n s may tend t o be f u l l y t h r e e dimensional
rather
than r o l l - l i k e
suggest that at finite solutions
in c h a r a c t e r .
amplitude (i.e.,
Moreover, these results
R >R c) the
may be u n s t a b l e and t h e m o t i o n a t f i n i t e
three-dimenslonal.
Lastly,
two-dimensional a m p l i t u d e may become
in the case o f a f a u l t / f r a c t u r e
zone g e o m e t r y
(H 2 <<1, Hi 3 1 ) , T a b l e 1 shows t h a t Rc i s s e v e r a l o r d e r s o f m a g n i t u d e greater
than t h e v a l u e 4~ 2 f o r an i n f i n i t e
t a k e s t h e form o f a r o l l d i m e n s i o n o f t h e box. showed t h a t , para]lel
for
with This
its
axis parallel
is c o n t r a r y
insulated walls,
slab,
and t h e m o t i o n a t R = R c t o t h e long h o r i z o n t a l
t o the r e s u l t s
the r o l l s
their
axes
t o t h e s h o r t s i d e o f t h e box.
The r e s u l t s
in T a b l e 1 f o r a f a u l t / f r a c t u r e
zone geometry a r e in
r e a s o n a b l e agreement w i t h an a p p r o x i m a t e a n a l y t i c a l Lowell
(6).
velocity
The a n a l y t i c a l
calculations
boundary c o n d i t i o n s
condition
result
d e r i v e d by
were p e r f o r m e d by r e l a x i n g
on t h e v e r t i c a l
walls.
the
I f one r e p l a c e s the
qy= 0 a t y = O, H2 w i t h ~qz/~Z = 0 a t y = O, H2, t h e e i g e n f u n c t i o n s
become s e p a r a b l e , and e q u a t i o n this
o f Beck (1) who
were a l i g n e d w i t h
case, w i t h H 1 + ~ ,
(7) can be s o l v e d by s t a n d a r d methods.
H2<< 1, L o w e l l
In
(6) o b t a i n s :
R = 4~ 2 /H 2 c 2 With H2 = 0 . 0 1 ,
Rc
4 x 105
w h i c h is a b o u t ten p e r c e n t s m a l l e r than
t h e v a l u e found by t h e G a l e r k i n method. e x p e c t e d in v i e w o f the f a c t restrictive
in t h e a n a l y t i c a l
The a n a l y t i c a l a roll
with
its
results
that
T h i s u n d e r e s t i m a t e o f R i s t o be c the boundary c o n d i t i o n s were l e s s
calculations
a l s o show t h a t
axis along the strike Geophysical
T a b l e 1 shows t h a t material
with a fault
than in t h e G a l e r k i n method.
t h e f l o w a t R = R t a k e s p l a c e as c of the fault.
Implications
in a c l o s e d c o n t a i n e r o f w a t e r - s a t u r a t e d
or fracture
zone g e o m e t r y , e . g . ,
porous
w i t h H2 = 0 . 0 1 ,
the
376
R.P. ~ i i
and C.-T.
Shyu
critical
R a y l e i g h number is n e a r l y 4.5 x 10 5 .
possible
in n a t u r a l
and a f a u l t
systems?
5, No. 6
Are such h i g h R a y l e i g h numbers
Assuming a t e m p e r a t u r e g r a d i e n t
8 = iO0°C/km
d e p t h o f 3 km, which a r e r e a s o n a b l e f o r a g e o t h e r m a l r e g i o n ,
we e s t i m a t e v a l u e s o f the p h y s i c a l
p a r a m e t e r s from S t r a u s and S c h u b e r t ( 7 ) :
pfs = I cal/cm 3 - °C,~ = 1.5 x 10-3/°C,v -
Vol.
°C - s e c .
e,v,l
these parameters
are average
into the Rayleigh
onset of convection
not unrealistic
separation
for
fault zone.
the p e r m e a b i l i t y
fractures
within
due t o a s e r i e s o f f l a t h, Bear (8, p.
= 2 x 10-3cm/sec, ~ = 5 x 10-3cal/cm
over the depth
range.
Substituting
number gives K =3 x 10-8cm 2, for the
in a 50 m wide
value,
from i n t e r c o n n e c t e d permeability
values
This
is quite a high,
in a f a u l t
but
zone m a i n ] y a r i s e s
t h e r o c k volume; and assuming a parallel
fractures
o f w i d t h d and
164) has shown t h a t K = d3/12h
This,
if
on t h i s
K = 3 x IO-8cm 2, h = 100 cm, then d = 3.3 x I0-2cm. s c a l e do n o t appear u n r e a s o n a b l e f o r a f a u l t
the earth's
crust.
in such systems, critical
that
the a c t u a l
gradient
we emphasize t h a t
a l o n g the w a l l s
of convection in t i m e ,
R a y l e i g h number l i e s
zone in
convection occurs rather
close to the
the a s s u m p t i o n o f a u n i f o r m t h e r m a l
is o n l y a p p r o p r i a t e
in a n a t u r a l
the g r a d i e n t
be m a i n t a i n e d .
fault
or fracture
insulated
in the a d j a c e n t
In t i m e t h e r e w i l l
a c r o s s the w a i l s ,
as a c o n d i t i o n zone.
for
boundaries.
convection
f l o w may d e c l i n e
For t h i s
is
initiated.
As c o n v e c t i o n proceeds
be a d e c r e a s e in t h e l a t e r a l
porous c o n t a i n e r w i t h
and perhaps t o change i t s
cell
is reduced.
t i m e dependent a s p e c t s o f c o n v e c t i o n
in a
An e x a m i n a t i o n o f t h e s e p r o b l e m s
research.
r e s e a r c h was s u p p o r t e d by t h e U. S. G e o l o g i c a l Survey, Interior
In
may be somewhat more c o m p l i c a t e d
Acknowledgments
Department o f
pattern,
however, t h e c o n v e c t i v e
temperature gradient
insulated walls.
be a s u b j e c t o f f u t u r e
gradient
r e a s o n , one m i g h t e x p e c t c o n v e c t i o n
conducting walls
than in c o n t a i n e r s w i t h
not
tend t o have the appearance
At l a r g e t i m e s ,
s i n c e the d r i v i n g
summary, t h e f i n i t e - a m p l i t u d e ,
This
the o n s e t
impermeable r o c k m a t r i x w i l l
and hence the w a l l s w i l l
t o become somewhat more v i g o r o u s ,
will
if
a t v a l u e s o f R>Rc, and heat is conducted t h r o u g h the v e r t i c a l
boundaries,
after
or fracture
however, t h a t
number.
Finally,
of
One m i g h t e x p e c t ,
Fractures
under USGS Grant No.
14-O8-0001-G-365.
VOl. 5, ~b. 6
CONVECfION IN A ~TER-SATURATED POROUS BOX
Nomenclature C C° I
-
v e c t o r o f expansion c o e f f i c i e n t s o f t r i a l
solutions
component expansion c o e f f i c i e n t s o f t r i a l
solutions
d
fracture width
g
acceleration due to gravity
h
fracture separation
dimensionless horizontal box lengths hl,H 2 K permeability of rock -
k
unit vector in z direction
L
dimensional box height
LI,L 2 -
horizontal box dimensions
MA,MB h
matrices arising in Galerkin formulation
P
-
unit vector in z direction dimensionless perturbation pressure dimensional f l u i d pressure
+
q,qx,qy,qz-dimensionless perturbation velocity, components R
dimensionless Rayleigh number
R
critical
s
s p e c i f i c heat o f f l u i d
T
temperature
T o T
temperature at base o f box
C
Rayleigh number
ten~perature at surface
S
v
-
Darcy v e l o c i t y o f f l u i d
x,y,z
c a r t e s i a n c o o r d i n a t e s , z p o s i t i v e downwards
-
therma] expansion c o e f f i c i e n t
8
-
geothermal g r a d i e n t
0
-
dimensionless p e r t u r b a t i o n temperature
Oi,ek,X
and c a r t e s i a n
t r i a l temperature function in Galerkln formulation
-
thermal conductivity of saturated material
-
kinematic viscosity of f l u i d
pf -
f l u i d density
377
378
R.P. Lowell and C.-T. Shyu
Vol. 5, hb. 6
REFERENCES
I.
J. L. Beck, Phys. Fluids, 15, 1377 (1972).
2.
A. Zebib and D. R. Kassoy, Phys. Fluids, 20, 4 (1977).
3.
S. H. Davis, J. Fluid Mech. 3(3, 465 (1967).
4.
I. Catton, Jour. Heat Transfer,
5.
E. R. Lapwood, Proc. Cambridge Phil., Soc. 44, 508 (1948).
6.
R. P. Lowell, Semi-annual grant #14-08-0001-G-365,
9_.22,186 (1970).
technical
letter report no. I, USGS
10p (1977).
7.
J. M. Straus and G. Schubert, J. Geophys. Res., 82, 325 (1977).
8.
J. Bear, Dynamics of Fluids in Porous Media, Elsevier, New York, 764p (1972).