On Axially Symmetric Vibrations of Fluid Filled Poroelastic Spherical Shells

doi:10.4236/oja.2011.12003

Open Journal of Acoust i c s , 2011, 1, 15-26

doi:10.4236/oja.2011.12003 Published Online September 2011 (http://www.SciRP.org/journal/oja)

On Axially Symmetric Vibrations of Fluid Filled

Poroelastic Spherical Shells

Syed Ahmed Shah1, Mohammed Tajuddin2

1Department of Mathematics, Deccan College of Engineering and Technology, Hyderabad, India

2Department of Mathematics, Osmania University, Hyderabad, India

E-mail: ahmed_shah67@yahoo.com

Received July 27, 2011; revised August 15, 2011; accepted August 19, 2011

Abstract

Employing Biot’s theory of wave propagation in liquid saturated porous media, waves propagating in a hol-

low poroelastic closed spherical shell filled with fluid are studied. The frequency equation of axially sym-

metric vibrations for a pervious and an impervious surface is obtained. Free vibrations of a closed spherical

shell are studied as a particular case when the fluid is vanished. Frequency as a function of ratio of thickness

to inner radius is computed in absence of dissipation for two types of poroelastic materials each for a pervi-

ous and an impervious surface. Results of previous works are obtained as a particular case of the present

study.

Keywords: Biot’s Theory, Axially Symmetric Vibrations, Radial Vibrations, Rotatory Vibrations, Spherical

Shell, Elastic Fluid, Pervious Surface, Impervious Surface, Frequency

1. Introduction

Using exact three dimensional equations of linear elas-

ticity, Ram Kumar [1] studied the axially symmetric vi-

brations of fluid-filled spherical shells. Rand and Di-

Maggio [2] studied the vibrations of fluid filled elastic

spherical and spheroidal shells. Employing Biot’s [3]

theory, Paul [4] discussed the radial vibrations of poroe-

lastic spherical shells. Chao et al. [5] presented the theo-

retical and experimental results regarding wave propaga-

tion in porous formations. Ahmed Shah [6] investigated

the axially symmetric vibrations of fluid-filled poroelas-

tic circular cylindrical shells of various wall-thicknesses

in the absence of dissipation. Sharma and Sharma [7]

studied the three dimensional free vibrations of transra-

dially thermoelastic spheres. Ahmed Shah and Tajuddin

[8] studied torsional vibrations of poroelastic spheroidal

shells.

In the present analysis, wave propagation in fluid

filled poroelastic spherical shells is studied in absence of

dissipation. Frequency equation each for a pervious and

an impervious surface is obtained employing Biot’s [3]

theory of wave propagation in liquid saturated poroelas-

tic solid. Biot’s [3] model consists of an elastic matrix

permeated by a network of interconnected spaces satu-

rated with liquid. Frequency equation of axially symmet-

ric vibrations each for a pervious and impervious surface

is obtained for fluid filled and empty poroelastic spheri-

cal shells. The frequency equations of radial and rotatory

vibrations are obtained as a particular case. Non-

dimensional frequency as a function of ratio of thickness

to inner radius is computed for pervious and impervious

surfaces in each case, i.e., fluid filled and empty poroe-

lastic spherical shell in absence of dissipation. The re-

sults are displayed graphically for two types of poroelas-

tic materials and then discussed. Results of some previ-

ous works are shown as a particular case of the present

investigation. By ignoring the liquid effects, and after

some rearrangement of terms, results of purely elastic

solid are shown as a particular case considered by Ram

Kumar [1].

2. Governing Equations

The equations of motion of a homogeneous, isotropic

poroelastic solid [3] in presence of dissipation b are



2

22

12111122 12

2

ΦΦΦΦ ΦΦ,

t

PQ ρρ b



 





2

22

12121222 12

2

ΦΦΦΦ ΦΦ,

t

QR ρρ b







S. A. SHAH ET AL.

16



2

1111122 12

2

ΨΨΨΨΨ,

t

Nρρ b



 





2

12 122212

2

0ΨρΨ ΨΨ,

t

tρb







 (1)

where 1, 2, Ψ1, Ψ2 are potential functions of r, θ and

time t; P (=A + 2N), N, Q, R are all poroelastic constants

and



ik (i, k = 1,2) are the mass coefficients following

Biot [3]. The poroelastic constants A, N correspond to

familiar Lame constants in purely elastic solid. The co-

efficient N represents the shear modulus of the solid. The

coefficient R is a measure of the pressure required on the

liquid to force a certain amount of the liquid into the ag-

gregate while total volume remains constant. The coeffi-

cient Q represents the coupling between the volume

change of the solid to that of liquid and

22

2

2222

12cot

.

θ

rr θ

rr r

 

 



 (2)

The equation of motion for a homogeneous, isotropic,

inviscid elastic fluid is

2

22

f

1Φ

Φ,

Vt



  (3)

where  is displacement potential function and Vf is the

velocity of sound in the fluid.

The stresses



ik and the liquid pressure s of the poroe-

lastic solid are

 

2, ,,,

ik ikik

σNeAe Qδik rθφ

,sQeR (4)

where ik is the well-known Kronecker delta function.

The fluid pressure σf is given by

2

Φ,

ff

σρ

t



  (5)

where



f is the density of the fluid.

3. Solution of the Problem

Let (r,



, φ) be the spherical polar coordinates. Consider

a homogeneous, isotropic, poroelastic spherical shell

filled with inviscid elastic fluid. Let the inner and outer

radii be r1 and r2 respectively so that the thickness of

poroelastic spherical shell is h [=(r2r1) > 0]. Axially

sym- metric vibrations of the spherical shell is character-

ized by the displacement field of solid (,,0)uuv

and

liquid (,,0)UUV



where u, v, U and V are functions of

r, θ and time t. For axially symmetric vibrations of

poroelastic spherical shell, the displacement components

and solid and liquid, respectively are given potential

functions 1, 2, Ψ1, Ψ2 as

2

11 1

2

ΦΨ Ψ

1cot

,

θ

urrr θ

θ

 

 



2

11 1

ΦΨ Ψ

11

v,

rθrθrθ

 







2

22 2

2

ΦΨ Ψ

1cot

,

θ

Urrr θ

θ

 

 





2

22 2

ΦΨ Ψ

11

V.

rθrθrθ

 





 (6)

Similarly, the displacement vector of fluid is

(,,0)

fff

uuv





, where

Φ1Φ

, .

ff

uv

rrθ







 (7)

Solution of Equation (1) is





111112222

Φ()()()()(cos )e,

i ωt

nnn nn

Aj ξrByξrAjξrByξrP θ

22 22

2111122 222

Φ()()) (cos )e,

i ωt

n1n1n2n n

AδjξrBδyξrAδj(ξr)B δy(ξrP θ



 







133 33

Ψ))(cos )e,

i ωt

nnn

Aj(ξrBy(ξrP θ



12

23333

22

Ψ(()(cos )e.

i ωt

nnn

KAj ξr)B yξrP θ

K

  (8)

In Equation (8), jn, yn are Spherical Bessel functions of

first and second kind respectively, Pn is Legendre poly-

nomial of degree n (n is the order of spherical harmonic),

A1, B1, A2, B2, A3, B3 are constants, ω is circular fre-

quency. Here i is complex unity or i2 =1 and

1

k, 1,2,3

k

ξωVk



 (9)











1

222

11121222 , 1,2

kk

δRKQKVPR QRKQKk





 



(10)

11 1

11 1112122222

, , ,KρibωKρibωKρibω

 

 (11)

also 11

22

ππ

()(z), ()().

22

nn

jzJyzY z

zz



 (12)

S. A. SHAH ET AL.

17

In Equation (9), V1, V2 are the dilatational wave ve-

locities of first and second kind, respectively and V3 is

shear wave velocity.

A bounded solution of Equation (3) is

Φ()(cos )e,

i ωt

fn fn

Aj ξrP θ (13)

where Af is constant and

1

f.

f

ξωV



 (14)

Substituting Equation (13) into Equation (5), the fluid

pressure is

()(cos )e.

2i ωt

fffnfn

σAρω jξrP θ  (15)

Dilatations of solid and liquid respectively, are

22

12

eΦ, Φ. (16)

Now the required displacements, stresses and liquid

pressure are





1 111 122 132 143 153 16f17

()B()()()()()()(cos )e,

i ωt

f n

uuAMrMrAMrBMrAMrBMrAMrP θ    (17)





1 211 222 23224325326f27n

()()()()()()()P(cos )e,

i ωt

rr f

σsσAMrBMrAMrBMrAMrBMrAMr θ  (18)



1 311 322332343 353 36

d(cos )

()()()()()()sin e,

d

i ωt

n

rθ

Pθ

σAMrBMrAMrBMrAMrBMr θ

θ

 (19)





1411422 432 44f47

()()()()()(cos )e,

i ωt

f n

sσAMrBMrAMrBMrAMrP θ  (20)



1 411 422 43244f47

()()()()()(cos )e,

fi ωt

n

σ

sANrBNrA NrBNrA NrPθ

rr



 

 (21)

where the elements Mik(r) and Nik(r) are























111 1121113221422

, , , ,

nnn n

Mr ξjξrMrξyξrMrξjξrMrξyξr

 

 

 









153 16317

11

, , ,

nnfnf

nn nn

Mr jξrMr yξrMr ξjξr

rr







2222222

1

2111111 111 11

2

1

2

() δnn n

nn

ξ

Mr PQQ RδξjξrAQQδRδjξrAQQδRδjξr

rr



 

 



2222222

1

221 11n111n11 11

2

1

2,

n

nn

ξ

Mr PQQδRδξyξrAQQδRδyξrAQQδRδyξr

rr



 

 



2222222

2

23222222 n2222

2

1

2,

n n

nn

ξ

Mr PQQδRδξjξrAQQδRδjξrAQQδRδjξr

rr



 

 



222 2222

2

24222n222 2222

2

1

2

ξyξ

nn

ξ

Mr PQQδRδξrAQQδRδyrAQQδRδyξr

rr



 

 

3

25n 33

2

2( 1)2( 1)

()() (),

n

Nn nξNn n

Mr jξrjξr

rr













32

2633 27

2

21 21

()()(), ()(),

nnfnf

Nn n+ξNn n

Mr yξryξrMr ρwj ξr

rr







  

11

3111 3211

22

, ,

nnnn

NξNξ

NN

Mr jξrjξrM ryξryξr

rr





  

22

3322 3422

22

(), (),

nnn n

NξNξ

NN

Mr jξrjξrMryξryξr

rr













2 2

353n 33363n 33

2 2

12 12

N

r, ,

n n

NnnNNnnN

Mr ξjξjξrMrNξyξryξr

rr

 

 











22 1

411 1111

2

1

2

() nn n

nn

ξ

Mr QRδξjξrjξrjξr

rr







 

 









S. A. SHAH ET AL.

18



 





22 1

421 1n1n11

2

1

2

() n

nn

ξ

Mr QRδξyξryξryξr

rr







 

 











 





22 2

4322 n222

2

1

2

nn

ξ

Mr QRδξjξrjξrjξr

rr







 

 











 





22 2

442 2222

2

1

2,

nn n

nn

ξ

Mr QRδξyξryξryξr

rr



 

 





2

4546 47

()0, ()0, ()(),

fnf

Mr Mr Mrρω jξr



 





 



2

21

23 1

411 1n1n1n11

23

2ξ21

2

ξjn

nn nn

ξ

Nr QRξjrjξrξrjξr

rrr





 



 

 







 





 



2

21

23 1

42111n1n 11

23

2ξ21

2

() y

n n

nn nn

ξ

Nr QRδξyξrξryξryξr

rrr



 



 









 





 



2

22

23 2

432 22222

23

221

2r

nnn n

nn ξnn

ξ

Nr QRδξjξrjξrjξjξr

rrr



 



 









 





 



2

22

23 2

442 22222

23

221

2

() δξ

r

n

nn n

nn ξnn

ξ

Nr QRξyξryξryryξr

rr



 



 

 





2

45 46 47

()0, ()0, ()().

ffnf

NrNrNr ρωξ jξr



 (22)

In Equation (22), a prime over jn or yn represents dif-

ferentiation with respect to r.

4. Boundary Conditions-Frequency

Equation

The outer surface of the poroelastic spherical shell is

assumed to be free from traction. Continuity of radial

displacement and fluid pressure is assumed at the inter-

face of solid and fluid. Thus the boundary conditions for

a fluid-filled poroelastic spherical shell, in case of a per-

vious surface are

0, 0, 0, 0

frrfrθf

uu σsσσsσ

at r = r1,

0, 0, 0,

rr rθ

σsσs at r = r2. (23)

Similarly, the boundary conditions for a fluid-filled

poroelastic spherical shell, in case of an impervious sur-

face are

0, s0, 0, 0,

f

frr frθ

σ

s

uu σσσ rr







at r = r1,0, 0, 0,

rr rθ

s

σsσr





 at r = r2. .(24)

Substitution of Equations (17)-(20) into the boundary

conditions (23) result in a system of seven homogeneous

algebraic equations in seven constants A1, B1, A2, B2, A3,

B3 and Af. For a non-trivial solution, the determinant of

the coefficients must vanish. By eliminating these con-

stants, the frequency equation of axially symmetric vi-

brations of a fluid-filled poroelastic spherical shell in

case of a pervious surface is

0, ,1,2,3,7.

ik

Aik (25)

In Equation (25), the elements Aik are

1

(); 1,2,3,4 and 1,2,7,

ik ik

AMr ik





522632742

(), (), (), 1,2,6,

kk kk kk

A MrAMrA Mrk





37 57 67 77

0, 0, 0, 0.AAAA



 (26)

In Equation (26), the elements Mik(r) are defined in

Equation (22).

Arguing on similar lines, Equations (17)-(19), (21)

together with the Equation (24) yield the frequency equa-

tion of axially symmetric vibrations of a fluid-filled po-

roelastic spherical shell in case of an impervious surface

to be

0, ,1,2,7,

ik

Bik (27)

where the elements Bik are

, 1,2,3,5,6 and 1,2,7,

ik ik

BAi k





S. A. SHAH ET AL.

19

441

(), 1,2,7,

kk

BNrk

7k4k 277

N

(), 1,2,6, and 0,BrkB  (28)

where Mik(r) and Nik(r) are defined in Equation (22).

By eliminating liquid effects from frequency equation

of a pervious surface (25), that is, setting b0,



120,



220, (AQ2/R) , N



, Q0, R0 and after re-

arrangement of terms, the results of purely elastic solid

are obtained as a particular case considered by Ram

Kumar [1]. The frequency equation of an impervious

surface (27) has no counterpart in purely elastic solid.

The order of spherical harmonic n takes different integer

values. When n = 0, radial vibrations are obtained

whereas n = 1 results in rotatory vibrations. For n = 2

spheroidal vibrations are obtained in which the sphere is

distorted into an ellipsoid of revolution becoming prolate

or oblate according to the phase of motion.

4.1. Frequency Equation for an Empty

Poroelastic Spherical Shell

When the fluid density is zero, that is,



f = 0 the fluid-

filled poroelastic spherical shell will become an empty

poroelastic spherical shell. Thus, the frequency equation

of pervious surface (25) under suitable boundary condi-

tions reduce to

0, 2,3,4,5,6,7 and 1,2,3,4,5,6,

ik

Ai k (29)

where the elements Aik are defined in Equation (26) are

now evaluated for



f = 0.

Equation (29) is the frequency equation of axially

symmetric vibrations of an empty poroelastic spherical

shell in case of a pervious surface.

Similarly, the frequency equation of axially symmetric

vibrations of an empty poroelastic spherical shell for an

impervious surface under suitable boundary conditions is

0, 2,3,4,5,6,7 and 1,2,3,4,5,6,

ik

Bi k (30)

where the elements Bik are defined in Equation (28) are

now evaluated for



f = 0.

4.2. Frequency Equation of Radial Vibrations

When the order of spherical harmonic n = 0, the fre-

quency equation of axially symmetric vibrations of fluid

filled spherical shell Equation (25) reduce to the fre-

quency equation of radial vibrations of fluid filled

spherical shell in case of a pervious surface under suit-

able boundary conditions. Radial vibrations involve u

and uf as the only non-zero displacement components.

Thus the frequency equation of radial vibrations of fluid

filled poroelastic spherical shell for a pervious surface is

1112 13 14 17

2122 23 24 27

4142 43 44 47

51 5253 54

71 7273 74

0,

0

AAAAA

AA AAA

AA AA

AAAA

 (31)

where the elements Aik are defined in Equation (26) are

now evaluated for n = 0.

Similarly, the frequency equation of radial vibrations

of fluid-filled poroelastic spherical shell in case of an

impervious surface is

11 1213 14 17

21 22232427

41 42434447

51 5253 54

71 727374

B0,

0

BBBBB

BBBB

 (32)

where the elements Bik are defined in Equation (28) are

now evaluated for n = 0.

When the fluid density is zero in Equation (31), it be-

comes the frequency equation of radial vibration of an

empty poroelastic spherical shell under suitable bound-

ary conditions as

21 2223 24

41 4243 44

51 5253 54

71 7273 74

0,

AAAA

AAA A

AAAA

 (33)

where the elements Aik are defined in Equation (26) are

now evaluated for



f = 0 and n = 0.

In a similar way, the frequency equation of radial vi-

brations of an empty poroelastic spherical shell for an

impervious surface is

21 222324

41 424344

51 525354

71 727374

0,

BBBB

 (34)

where the elements Bik are defined in Equation (28) are

now evaluated for



f = 0 and n = 0.

The frequency equation of radial vibrations of an

empty poroelastic spherical shell Equation (33) of a per-

vious surface was also studied by Paul [4] with the

boundary conditions 0, 0,

rr

σs



 at r = r1 and r2.

4.3. Frequency Equation of Rotatory Vibrations

When the order of spherical harmonic n = 1, the fre-

quency equation of axially symmetric vibrations of fluid

filled spherical shell Equation (25) reduce to the fre-

S. A. SHAH ET AL.

20

quency equation of rotatory vibrations of fluid filled

spherical shell in case of a pervious surface. Thus the

frequency equation of rotatory vibrations of fluid filled

poroelastic spherical shell for a pervious surface is

0, ,1,2,3,7.

ik

Aik (35)

The elements Aik appearing in Equation (35) are de-

fined in Equation (26) are now evaluated for n = 1.

Similarly, the frequency equation of rotatory vibra-

tions of a fluid filled poroelastic spherical shell in case of

an impervious surface is

0, ,1,2,3,7,

ik

Bik (36)

where elements Bik appearing in Equation (36) are de-

fined in Equation (28) are now evaluated for n = 1.

Setting n = 1 in Equations (29) and (30), the frequency

equations of rotatory vibrations of empty poroelastic

spherical shells of a pervious and an impervious surface

respectively, are obtained.

5. Non-Dimensionalisation of Frequency

Equation

To analyze the frequency equations of radial and rotatory

vibrations of fluid-filled and empty poroelastic spherical

shells in the cases of pervious and impervious surfaces, it

is convenient to introduce the following non-dimensional

variables:

1111

12 34

, , , ,aPH aQH aRH aNH



 11 11

11 1112122222

ρ, , , ,

f

mρmρρ mρρ tρ

ρ





 

1212 1211

010 20330

(), (VV), (), , Ω,

f

xVV yzVVmVVωhC



 

  (37)

where  is non-dimensional frequency, H = P + 2Q + R,



=



11 + 2



12

+



22, C0 and V0 are the reference veloci-

ties (C0

2 = N/, V0

2 = H/), h is the thickness of the

poroelastic spherical shell. Let

2

112

r1

, so that 1, .

r

hhg

gg

rrg





(38)

Employing the non-dimensional parameters defined in

Equations (37), (38) and using the relations given in A-

bramowitz and Stegun [9]

01

2

sinsin cos

(), (),

zzz

jz jz

zz

z



232

31 3

()sin cos,

z

jzz z

zz



 





01

2

232

coscos sin

(z), (),

31 3

()cos sin,

z

zzz

yyz

zz

z

yzz z

z

 



 





the frequency equation of radial vibrations of a fluid

filled spherical shell in case of a pervious surface Equa-

tion (31) reduce to

0; ,1,2,3,4,5,

ik

Cik (39)

where elements Cik appearing in Equation (39) are

11111211

11

sin()cos(), Ccos()sin(),CTT TT

TT



1322 14221544

22 4

11 1

sin()cos(), cos()sin(), sin()cos(),CTTCTTCTT

TT T





22

4

21122 13 11141

1

4δδ sin( )4cos( ),

a

CaaaaTTaT

T











22 4

22122 13 11141

1

4

δδ cos( )4 sin( ),

a

CaaaaT TaT

T



 







22

4

23122 23 22242

2

4δδsin()4cos( ),

a

CaaaaTTaT

T











2

22 44

24122 23 22242254

2

24

4Ω

cos()4sin(), Csin(),

(1)

ata

CaaaδaδTTaT T

TgT



 

 



22

313 12113223 111

()sin(), ()cos(),CaδaTT Ca aδTT

2

22

4

33322223423 222354

2

4

Ω

(δ)sin(), ()cos(), sin(),

(1)

ta

CaaTTCaaδTTC T

gT

 



S. A. SHAH ET AL.

21

C41, C42, C51, C52 = Similar expressions as C21, C22, C31,

C32 with T1 replaced by T5,

C43, C44, C53, C54 = Similar expressions as C23, C24, C33,

C34 with T2 replaced by T6,

C45 = 0, C55 = 0. (40)

Similarly, the frequency equation of radial vibrations

of a fluid filled poroelastic spherical shell for an imper-

vious surface in non-dimensional form is

0; ,1,2,3,4,5,

ik

Dik (41)

Where ; 1,2,4, 1,2,3,4,5,

ik ik

DCi k

222

3123 1113 1211

()sin()()cos(),DaaδTT aδaT T 

222

32312113 1211

()cos()()sin(),DaδaT T aδaT T 

222

3323 2223 2222

()sin()()cos(),DaaδTT aδaT T 

222

343222232222

()cos()()sin(),DaδaT T aδaTT

22

44

354 4

22

4

ΩΩ

sin()cos(),

(1) (1)

ta ta

DTT

gT g





D51, D52 = Similar expressions as D31, D32 with T1 re-

placed by T5,

D53, D54 = Similar expressions as D33, D34 with T2 re-

placed by T6,

D55 = 0. (42)

The frequency equation of rotatory vibrations of a

fluid filled poroelastic spherical shell for a pervious sur-

face Equation (35) in non-dimensional form reduce to

0, ,1,2,3,7,

ik

Eik (43)

where the elements Eik are

1111 1211

22

11

222 2

1sin()cos(), 1cos()sin(),ETTE TT

TT

 



 



1322 1422

22

222 2

1sin()cos(), 1cos()sin(),ETTE TT

TT

 



 



1533 1633

2 2

33

22 22

cos()sin(), sin()cos(),ETTET T

TT



174 4

2

4

22

1sin( )cos(),ETT

T



 







22 22

4 4

214122 13 11122 13 111

2

1

12 12

4sin() cos(),

aa

EaaaaδaδTaaaδaδTT

T



 







22 22

44

22412213111 2 213111

2

1

12 12

4cos()sin(),

aa

EaaaaδaδTaaaδaδTT

T



 







22 22

4 4

234122 23 22122 23 222

2

12 12

4δδsin( )δδ cos( ),

aa

EaaaaaTaaaaTT

T



 







22 22

44

244122 23 22122 23 222

2

12 12

4δδ cos( )(δδ)sin(),

aa

EaaaaaTaaaaT T

T



 





44 44

25433 26433

22

33

121212 12

4sin()cos(), 4cos()sin(),

aa aa

EaTTEaTT

TT

 

 

 



22

44

27 44

222

44

ΩΩ

cos( )sin( ),

(1)(1)

ta ta

ETT

gT gT





44 44

31411 32411

22

11

66 66

E2sin(T )cos(), E2cos(T )sin(),

aa aa

aTa T

TT

 

 

 



44 44

33422 34422

22

66 66

2sin()cos(), 2cos()sin(),

T

aa aa

EaTTEaTT

T

TT

 

 

 



S. A. SHAH ET AL.

22

4444

3543433364343337

2 2

3 3

6666

3sin()cos(), 3cos()sin(), 0,

aaaa

EaTaTTEaTaTTE

TT

 

 

 

 





















22 22

4131 213121141231131 211

δsinδTcos, Eδcosδsin,Eaa TaaTaaTaaTT 



























22 22

433222 32222442322 32222

δVsin δcos, δcos δsin,E aTa aTTE aaTa aTT 

 

22

44

45 46 4744

22

2

44

ΩΩ

0, 0, cossin,

11

ta ta

EEET T

gT gT

 



E51, E52, E61, E62, E71, E72 = Similar expressions as E21,

E22, E31, E32, E41, E42 with T1 replaced by T5,

E53, E54, E63, E64, E73, E74 = Similar expressions as E23,

E24, E33, E34, E43, E44 with T2 replaced by T6,

E55, E56, E65, E66 = Similar expressions as E25, E26, E35,

E36 with T3 replaced by T7,

57 67 75 76 77

0, 0, 0, 0, 0.EEEEE (44)

Similarly, the frequency equation of rotatory vibra-

tions of a fluid filled poroelastic spherical shell for an

impervious surface Equation (36) in non-dimensional

form reduce to

0, ,1,2,37,

ik

Fik (45)

where

; 1,2,3,5,6, 1,2,3,4,5,6,7,

ik ik

FEi k 

22 2

413 12113 1211

( )(2)sin()2()cos(),FaδaTT aδaT T 

22 2

42312113 1211

( )(2)cos()2( )sin(),FaδaT TaδaT T 

222

433 22223 2222

()(2)sin( )2()cos(),FaδaTT aδaT T 

22 2

44322223 2222

()(2)cos() 2()sin( ),FaδaT TaδaT T

45 46

22

44

474 4

22 2

44

0, 0,

Ω2Ω

21sin()cos( ),

(1) (1)

FF

ta ta

F

TT

gT gT













F71, F72 = Similar expressions as E41, E42 with T1 re-

placed by T5,

F73, F74 = Similar expressions as E43, E44 with T2 re-

placed by T6,

F75 = 0, F76 = 0, F77 = 0. (46)

In Equations (40), (42), (44) and (46) the quantities T1,

T2, T3, T4, T5, T6, T7 are

11 11

22 22

444 4

123 4

Ω() Ω()Ω()Ω()

,, , ,

(1) (1)(1)(1)

ax ayazaz

TTT T

gg gmg

 

 

 

111

222

44 4

567

Ω() Ω() Ω()

, , ,

(1) (1) (1)

ax gay gaz g

TTT

ggg





 (47)

and 22

12

, δδ

in non-dimensional form are



1

22

13 112121323 12222

()()x ,δamamaaaamam 











1

22

23 112121323 12222

()()y .δamamaa aamam











(48)

6. Numerical Results and Discussion

Two types of poroelastic materials are considered to find

the frequency as a function of ratio of thickness of

spherical shell to inner radius. One poroelastic material is

sandstone saturated with kerosene designated as Mate-

rial-I [10]. The other poroelastic material is sandstone

saturated with water, Material-II [11]. The non-dimen-

sional physical parameters of Material-I and II are given

in Table 1.

Frequency Equations (39), (41), (43), (45) and the cor-

responding frequency equations of empty poroelastic

spherical shells each for a pervious and impervious sur-

face constitute a relation between non-dimensional fre-

quency Ω and ratio of thickness of the poroelastic

spherical shell to inner radius h/r1. When the values of

h/r1 are small it represents thin poroelastic spherical shell.

Thickness of the poroelastic spherical shell increases

with the increase of h/r1. As h/r1→∞ or r1→0, empty

poroelastic spherical shell becomes a poroelastic solid

sphere. To compute the frequency of fluid filled and

empty poroelastic spherical shells values of h/r1 are taken

in the interval [0.5,7]. These values of h/r1 represents

transition of spherical shell from a thin spherical shell to

moderately thick shell and then to thick spherical shell.

For fluid-filled poroelastic spherical shells, the values of

m and t are taken as m = 1.5 and t = 0.4.

Table 1. Material Parameters.

Material/Parameter a1 a2 a3 a4 m11 m12 m22

x

 y

 z



I 0.843 0.065 0.028 0.234 0.901 –0.0010.101 0.999 4.763 3.851

II 0.960 0.006 0.028 0.412 0.877 0 0.123 0.913 4.347 2.129

S. A. SHAH ET AL.

23

Non-dimensional frequency of radial vibrations (n = 0)

as a function of ratio of thickness to inner radius of a

fluid-filled and an empty poroelastic spherical shell is

presented in Figure 1 for Material-I each for a pervious

and an impervious surface.

From Figure 1 it is clear that frequency of a fluid

filled shell for pervious surface decreases in case of a

thin spherical shell. As the thickness of the spherical

shell increases the frequency increases gradually for

moderately thick spherical shell. Still with the increase of

thickness of the shell, the frequency remains constant.

The frequency of fluid filled spherical shell decreases for

thin shell in case of an impervious surface also and it is

slightly higher than the frequency of a pervious surface.

Then, as the thickness of the spherical shell increases the

frequency increases rapidly and for moderately thick

shell it remains constant. With the increase of thickness

of the shell, the frequency decreases and then remains

constant. The frequency of an impervious surface is al-

ways higher than that of a pervious surface in case of a

fluid filled spherical shell. The frequency of an empty

spherical shell slowly increases with the increase of the

thickness and for thick spherical shell it is constant. The

frequency of an empty spherical thick shell is higher than

that of a fluid filled thick shell. This is not true in case of

a thin spherical shell. Thus it is seen that the presence of

fluid is decreasing the frequency of thick spherical shell.

The frequency of an empty spherical shell for an imper-

vious surface is almost same as that of fluid filled mod-

erately thick shell. The frequency of fluid filled and

empty thick shells is same. The frequency of an imper-

vious surface is higher than that of a pervious surface in

case of empty spherical shell also. Thus the frequency of

an impervious surface is higher than that of a pervious

surface for an empty and a fluid filled spherical shell.

The variation of frequency of radial vibrations of a

fluid filled and an empty poroelastic spherical shell each

for a pervious an impervious surface is presented in Fig-

ure 2 for Material-II. The variation of frequency of fluid

filled shell is similar as discussed in Figure 1. But the

frequency of empty spherical shell for a pervious an im-

pervious surface is nearly same for thin and moderately

thick spherical shells. The frequency of an impervious

surface is higher than that of a pervious surface in case of

thick empty spherical shells. Presence of mass-coupling

parameter has no significant effect on the frequency of

fluid filled spherical shell in case of a pervious surface.

The absence of mass-coupling parameter in Mate-

rial-II is increasing the frequency of an impervious sur-

face for fluid filled spherical shells. This phenomenon is

reversed in case of empty poroelastic spherical shells

where the presence of mass-coupling parameter is in-

creasing the frequency of an impervious surface. Also it

is seen that the presence of fluid is decreasing the fre-

quency in case of a pervious surface while it is increas-

ing the frequency in case of an impervious surface for

both the materials.

Frequency of rotatory vibrations (n=1) of fluid filled

and empty spherical shells each for a pervious and an

impervious surface is presented in Figures 3 and 4 for

Material-I and Material-II, respectively. From Figure 3 it

is clear that the frequency of a fluid filled spherical shell

0

1

2

3

4

5

6

7

0.5 1.5 2.53.5 4.5 5.56.5

Ratio of thickness to i nner ra dius

Frequency

_____________Perv ious Surface

- - - - - - - - - - -Impervious Surface

Fluid-fill ed shel l

Fluid-fill ed shell

Empty shell

Figure 1. Frequency as a function of ratio of thickness to inner radius Radial vibrations of Fluid-filled and empty spherical

shells (Material-Ⅰ, n = 0).

S. A. SHAH ET AL.

24

0

1

2

3

4

5

6

7

8

0.5 1.5 2.5 3.5 4.5 5.5 6.5

Ratio of thickness to inner radius

Frequency

____________Pervious Surface

- - - - - - - - - - -Im pervious

Flui d-filled shell

Fluid-filled shell

Empty shell

Figure 2. Frequency as a function of ratio of thickness to inner radius Radial vibrations of Fluid-filled and empty spherical

shells (Material-Ⅱ, n = 0).

0

1

2

3

4

5

6

0.5 1.5 2.5 3.5 4.5 5.5 6.5

Ratio of thi ckness to inner radius

Frequency

____________Perv ious Surface

- - - - - - - - - - -Im pervious

Fluid-filled shellFluid-filled shell

Empt y shell

Figure 3. Frequency as a function of ratio of thickness to inner radius Rotatory vibrations of Fluid-filled and empty sphe rical

shells (Material-Ⅰ, n = 1).

varies in a staggered way when the thickness of the

spherical shell is small. With the increase of thickness it

remains almost constant. Frequency of thin shell is

higher than that of the frequency of moderately thick

shell and thick shell in case of a fluid filled shell. The

frequency of an impervious surface varies in staggered

form for small thickness of the fluid filled shell. But here

with the increase of thickness the frequency increases.

Thus the frequency of thick shell is higher than the fre-

quency of thin shell in case of fluid filled spherical shell.

S. A. SHAH ET AL.

25

0

2

4

6

8

10

12

0.5 1.5 2.5 3.5 4.5 5.5 6.5

Ratio of thickness to inner radius

Frequency

___________ _P er vio us Sur face

- - - - - - - - - - -I mpervious

Fluid-fi lled shel l

Flui d-filled shell

Em pty shel l

Empty shell

Figure 4. Frequency as a function of ratio of thickness to inner radius Rotatory vibrations of Fluid-filled and empty sphe rical

shells (Material-Ⅱ, n = 1).

Obviously, the frequency of an impervious surface is

higher than the frequency of pervious surface for thick

fluid filled spherical shells. Therefore, the presence of

fluid is increasing the frequency of an impervious sur-

face for thick shell. The frequency of an empty spherical

shell increases with the increase of thickness for a per-

vious surface. Frequency of an empty shell is higher than

the frequency of fluid filled shell. Thus the presence of

fluid is decreasing the frequency of a fluid filled shell for

a pervious surface. Frequency of an impervious surface

of empty spherical shell is lower than the frequency of a

fluid filled shell. Thus the absence of fluid in the spheri-

cal shell is decreasing the frequency of an empty shell in

case of an impervious surface for thick shell.

Figure 4 show the frequency of fluid filled and empty

spherical shell each for a pervious an impervious surface

in case of Material-II. Frequency of pervious and imper-

vious surface is almost same for thin fluid filled shell.

With the increase of thickness, the frequency of an

impervious surface is higher than the frequency of a per-

vious surface. In case of empty thin spherical shells,

again the frequency of pervious and impervious surface

is same. With the increase of thickness, the frequency of

a pervious surface is higher than the frequency of an im-

pervious surface. It is seen that the presence of mass-

coupling parameter has no significant effect in case of

thick fluid filled shell for a pervious surface. In case of

an impervious surface, the presence of mass- coupling

parameter is increasing the frequency of fluid filled thick

spherical shells. This phenomenon is reversed for empty

spherical shells where the absence of mass-coupling pa-

rameter is increasing the frequency of a pervious surface

while it has no effect on an impervious surface for thick

empty shells.

7. Concluding Remarks

The study of radial and rotatory vibrations of fluid-filled

and empty poroelastic spherical shells has lead to fol-

lowing conclusions:

1) The frequency of an impervious surface in case of

radial vibrations is higher than that of a pervious surface

in case of a fluid filled and empty spherical shells.

2) Mass-coupling parameter has no significant effect

on the frequency of fluid filled spherical shell for a per-

vious surface in case of radial vibrations.

3) The absence of mass-coupling parameter in Mate-

rial-II is increasing the frequency of an impervious sur-

face of fluid filled spherical shells in case of radial vibra-

tions.

4) Presence of fluid is increasing the frequency of an

impervious surface of thick spherical shell in case of

rotatory vibrations.

5) Presence of fluid is decreasing the frequency of a

pervious surface for rotatory vibrations.

6) Absence of fluid in the thick spherical shell is de-

creasing the frequency of an impervious surface for ro-

tatory vibrations.

S. A. SHAH ET AL.

26

7) Mass-coupling parameter is increasing the fre-

quency of fluid filled thick spherical shells of an imper-

vious surface in case of rotatory vibrations.

8. Acknowledgements

The authors are thankful to the editor, reviewers and the

editorial assistant for their suggestions and kind coopera-

tion in improving the quality of this paper.

9. References

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[3] M. A. Biot, “Theory of Propagation of Elastic Waves in

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[4] S. Paul, “A Note on the Radial Vibrations of a Sphere of

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[7] J. N. Sharma and N. Sharma, “Three Dimensional Free

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[8] S. Ahmed Shah and M. Tajuddin, “Torsional Vibrations

of Poroelastic Prolate Spheroids,” International Journal

of Applied Mechanics and Engineering, Vol. 16, 2011, pp.

521-529.

[9] A. Abramowitz and I. A. Stegun, “Handbook of Mathe-

matical Functions,” National Bureau of Standards, Wa-

shington, 1965.

[10] I. Fatt, “The Biot-Willis Elastic Coefficients for a Sand-

stone,” Journal of Applied Mechanics, Vol. 26, 1959, pp.

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[11] C. H. Yew, and P. N. Jogi, “Study of Wave Motions in

Fluid-Saturated Porous Rocks,” Journal of the Acoustical

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