Asymptotic Models of Fields in Dilute and Denselly Packed Composites

L*(12)

= -5-(A +/x )sin<£cos
6 *(i3) =

( A * + f)Rl

c o s y ^ , 6^(23) = (A* + / / ) i ? i s i n ^ ^ -

(2.98)

Similarly, using the transformation of coordinates (2.94) we obtain the operators &o a n d b\ in the cylindrical coordinate system:

(A*+2/z')£

0

0

/**&

K

0

(2.99)

0

/;* —

KTa£ ( A * + M * ) - R l ^ \

'Hi

61 =

(2.100)

fll

\(A*+/x*)i?1^

0

0

/

Thus, we have written the stress operators in the new sets of coordinates for the thin layer. We shall assume here that the elastic constants A*,/x* are of order e, that is, A* = e\*0, M* = e\*0,

(2.101)

Imperfect interface.

"Coated" conical

inclusion.

89

where A*,/i* are of the same order as A,/i, A0,/z0. As a consequence of (2.101), the stress conditions operator for the thin layer will be written in the form e~xBl +B\^

e~% + €'%

-»• e^&S + b{,

(2.102)

where the matrix differential operators by, b\ have the same form as bg, b\, respectively, but with the elastic constants A*,/i*:

((K + Wo)Tk ° 0 /i*£

K

° 0

\ (2.103)

and

6J =

o

' H i d
V(A:+ M :)i?i^

o

(2.104)

o

The same can be said about the Lame differential operator, which can be written as e~'C*0 + e-'-C'i -> e~T0 + e-%

-3i* -»• e~% + e- 2"i *^ .

(2.105)

The operators l*0 and ij for the thin layer are given by (2.95), (2.96) with the elastic constants A*,/i* (due to the assumption (2.101) and the change of coordinates (2.89)). 2.2.2.2

Problem for to*1)

In the previous section we obtained the expressions for the Lame and stress differential operators for the thin layer. We now write the problem for the leading terms of the boundary layer, eto*1)(^), ew°^(^), and etw**1)^,
Dipole tensors in spectral problems of elasticity

90

layer. The displacement fields are thus given by v° ~ # > , * ) + eX(0)w°W(t),

|£| G g,

v* ~ **(^e)+ex(^K(1)(C,^).Ce[o,i?o],¥'e[o,27r)I v ~ *(
(2.106)

|£| e K2 \ (ffUj*),

where the functions 3>°, ** and * are given by (2.87), and x(#) is the cutoff function5 defined in Section 2.1. The fields w^\ w°^ and u>*(1) satisfy the following equations: £°0{%)w°M(t)

= 0,

M\\
* o ( ^ ) « ' * ( 1 ) ( C , ¥ ' ) = 0 ) C e ( 0 , i 2 o ) , ¥>€[0,27r)

/: 0 (^)ti;( 1 )(0=0 ) ||{||>i2i+eieo. Here, the operators £., CQ have the form (2.16), while IQ has the form (2.95), with elastic constants A*,/x*. We can see that the latter operator depends only on the derivatives with respect to £. This means that l^w^ can be written in the following way: ^wf\Cp)=0,

^ < ( 1 ) ( C , V ) = 0 , ^W*M(£,
(2-108)

From (2.108) we can see that the dependence upon £ is linear for all components of w*^(C,ip), therefore, w*^ can be written as w*{1)tt,
+ U<1\cp),

(2.109)

where W ^ ) , U*M(
Imperfect interface.

"Coated" conical

inclusion.

91

In Fig. 2.7 we present both interfaces. We can see that for the first interface w°W is evaluated at ||£|| = i?j, while w*^ is evaluated at £ = 0. Similarly, for the second interface ti/ 1 ) is evaluated at ||£|| = Ri + sRo, while w*W is evaluated at ( = Ro. From now on, we keep in mind that the evaluation of a function at a point will be given either with respect to the coordinates (^1,^2), for w°^\ w^\ or with respect to ( for w*^. We thus re-write the displacement conditions, and consider their relation to w*^ as given by (2.109): Interface 1: w°W{Rlttp)

•(i)/ ,„*(!) =w*W(0,
-

ipe

[0,2TT)

Interface 2: w(1)(R1+eR0,
= R0W*{1X
«1,«2)

«1.«2)

w*^> ( R 0 , ¥>) = ™ ( 1 ) ( H i + £ ^ 0 . V>) ^ ' ( ^ ( O , v)

=

w01-1)^,^)

< = Ro

Fig. 2.7 The coating of width eRo between the inclusion and the surrounding matrix. The numbers 1 and 2 denote the interfaces. The relevant coordinates and elastic constants are shown for each layer, as well as the displacement conditions for wW.

The function w^ is assumed to be smooth for all values of ||£||, and therefore, it admits a Taylor expansion. We consider the Taylor expansion for wW at Rx+eRo: wW{R1+eR0,
dwW + £R0—— (Rlf
(2.111)

92

Dipole tensors in spectral problems of elasticity

so to the first-order approximation, w^(R1+eR0)=w^\R1,V>).

(2.112)

Jump in the displacement We now evaluate the jump in the displacement across the interface (denoted here by [w](Ri,(p)) by subtracting left-hand sides of (2.110), and using (2.112): [w](R!,
= RoWWfr),

(2.113)

so that the function W*' '(
W*W(
= ^-(w^(R1,ip)~w°^(R1,tp)).

(2.114)

We can also write from (2.110) the function U*^l\
B0&,v)u>W(e)(R1+£Ro,
- Kw^HRoM

= -$>*&)(„), (2.115)

Imperfect interface.

"Coated" conical

inclusion.

93

where * # ( " ) = ((A + 2 / i K A * , 2 ) 0 ) r , *£>(!/) = (A^, (A + 2 ^ 2 , Of, *£>(i/) = A(«/i,^,0) T , *£>(!/) *
=

V2M^2^I,0)T,

= ^ ( 0 , 0 , K,) r , *£>(,/) = ^ / x ( 0 , 0 , i ^ ) r .

(2.116) The functions S&J^ (i/) are written here in the Cartesian system of coordinates. It is important to note that because we assumed (2.101), the contribution of BQ<&* within the coating layer will appear at the next step of the asymptotic algorithm. Using (2.103) and (2.109) we obtain the following representation for the second term in (2.115)

{(\*0+2n*0)W^\v)\ bZw'W(Ro,
M:^ ( 1 V)

(2.117)

the latter yields that the stress field is independent of £ throughout the thin layer. We now write the stress condition at the interface 1. We evaluate the corresponding stresses to obtain 8_ bZw*(1\0,v)-B°o(-,u)w°W(R1,v)

= ^cj*°^(v),

(2.118)

where

*°W(v)

= ((A O + 2 M < > I , A O ^ , 0 ) T , * O ( 2 V ) = {\ou1,{Xo +

* o ( i V ) = A o (i/i,i*,0) r ,* o < 4 >(i') =

2^o)v2,0)T,

y/2iio{v2,vi,0)T

¥°<6>(»/) = V2fi o (0,0 ) i* 2 ) T ,* o < 6 >(i/) = V2/x o (0,0,^ 2 ) T . (2.119) We now combine the stress conditions (2.115) and (2.118) by using the fact that the stress field is independent of £, and in particular, b*0w*W(0,
=bm0w«»(Ro,
(2.120)

Dipole tensors in spectral problems of elasticity

94

Thus, we obtain

(B0£,u)wM ^ '

- B ^ ^ w ^ i R u v )

= -^>*^V),

"d?

(2-121)

3=1

where \0)v2,0)T,

* < V ) = ((A + 2fi - A0 - 2/x0)i/!, (A -

* ^ ( i / ) = ((A - A > 1 ; (A + 2^ - A0 - 2M<>2, 0 ) T , ¥<3>(I/)

= (A - A o ) ( ^ 2 , 0 ) T , *W(i/) = V2(M - / O K ^ i , 0 ) T ,

* < 5 V ) = y/2{» - /io)(0,0, ^ 2 ) T , *<6>(i/) = ^ ( / i - / O ( 0 , 0 , ^ ) r . (2.122) Taking into account (2.114) we re-write (2.115) in the form:

/^K(w^{Rl>lf)^woW{Ru(fi))\

^wPiR^-w^iR!,?)) \

(2.123)

^(wi1\R1,
J

Here, the right-hand side of (2.123) is written in the cylindrical system of coordinates, therefore, we shall write the operators BQ and BQ as: ' arr(wr i

',w]p') ' (i)

W\

(2.124)

B0(^,u)wW(t)

\

/

Imperfect interface.

"Coated" conical

inclusion.

95

and

/<,K (1) X (1) )\ B°0{l,v)w°W(£)

(2.125)

= -

\

»o-it-

)

where a^,.,a°v are the stress operators in the polar system of coordinates. In (2.118), (2.121) we have written the contribution of the leading order to the stress field in Cartesian coordinates. We now write the \I> functions in cylindrical coordinates, noting that SE^', y!/0"' are of a similar form because ^ 0 ) _ q,U) _ q,°U)

(2.126)

therefore *(1)(V)= |

-(\ + H - A0 - fJ-o) - ( M ~ Mo) cos 2 ^ ' {fi-li0)sm2ip 0

' - ( A + /i - A0 - fj,0) + (/i - /z 0 )cos2<^ * (y>) = I -(n-ii0)Bm2ip 0 (2)

*(3)(v) = (

(A —A 0 )\ /sin2
*&(/2(/z - Mo) ( 0 \ sin

, sin2<£ = 1/2 — 1/2 cos 2y?, sin 2

Dipole tensors in spectral problems of elasticity

96

Hence, we have derived all t h e terms in (2.121), (2.123) in t h e cylindrical system of coordinates. Therefore, we substitute t h e relevant terms in these coordinates. We shall analyse t h e problem for t h e first two components, which is t h e plane strain problem and obtain t h e functions wr ' , w\p ' , w° , Wp . We also analyse t h e out-of-plane shear problem t o obtain urz , w° . Plane strain problem We will now analyse t h e problem for t h e first two components of t h e displacement fields in cylindrical coordinates. In t h e stress conditions given by (2.123), we substitute (2.124), (2.125) a n d ^ in t h e polar coordinates (written similarly as in (2.127)), to obtain:

-arr{w^\w^;Ri,ip)

- (ci + C 2 ) ( A + /J) + (c 2 - ci)/xcos2<£> - Ac3

-X/2/XC4sin2y = -

K

+ O 2 M ° (wPiRuip)

- ^(fr,y>)),

(2.128)

-(Tr

= -£(w£\R1,v)-w°vW(R1,

(2.129)

We re-write b o t h conditions (keeping in mind t h e notation for t h e j u m p in the displacement) as follows

M^ 1 ),«#>;£!,¥>) = ^ I M ^ C D ] ^ ^ ) _ (Cl +c2)(X + fx) - Ac 3 ito

+(c2 — ci)ficos2ip

arv(w(1\wW]R1,¥>)

— v2(iC4sm2
= !^[wW}(R1,¥>)

+

-\/2/xc 4 cos2(/?,
(2.130)

(c1-c2)tism2tp

(2.131)

We also re-write t h e stress condition (2.121) a n d use (2.122), (2.124), (2.125) a n d (2.127) t o obtain: arr(wi1\wW-,Ru
= -(\ +

Li-\0-ti0)(c1+c2)

Imperfect interface.

"Coated" conical

- ( A - A 0 )c 3 - ( / i - n0)(ci - c2)cos2(parv(w?\wW;Ri,
-

G0T^W0^\W0^;RX^)

inclusion.

y/2(n-

/x0)c4sin2,

97

(2.132)

= -(/x - fi0)(c2 - c 1 )sin2^

-V2(/x - /x0)c4 cos 2p, v? € [0, 2TT).

(2.133)

The system of equations (2.130)-(2.133) describes the boundary value problem for the functions {wr , w\p , u>r > ifJ }• We have incorporated the information about the thin layer, such as the elastic constants A*,/j*, and the width RQ into the interface condition. We need to construct the solution in order to find the asymptotics of wr ', wlp at infinity. We shall solve the problem by using the complex potentials. Complex potentials We shall solve the system of equations by representing the displacement fields in the form of the Kolosov-Muskhelishvili complex potentials (we refer to the book by Muskhelishvili, 1953), <j> and tp: wP + iw{^ = ^e-^ixcpiz)

- z(j)'(z) - ip'{z)) (2.134)

o(1)

«V where wr w° , w^ ip are the potentials

+ iw°v

{1)

= 5 ^ e - ^ ( x o 0 o ( z ) - zWM

-

WM),

,w\p' are the components of displacement in the matrix, while ' are the components of displacement within the inclusion, , complex potentials for the matrix and (f>0, xp0 are the complex for the inclusion, and _ A 4- 3/x A + /i

_ A0 + 3fi0 A0 + Ho

The representations for the stresses in terms of the complex potentials ip, <j>, are given below (see, for example, Muskhelishvili (1953), eq.(39.4)): arr + iarv = 4f(z) + '0(z) + Vjz) - e^[z
98

Dipole tensors in spectral problems of elasticity

field u>°W i s non-singular, while the displacement field w^ decays at infinity. Therefore the corresponding complex potentials must satisfy these constraints: oo

oo

~

oo

00

* = £ ^> ^ = £ §r' *° = £««*"> ^ = £ b ^ n > n=l

n=l

n=0

(2-136)

n=0

where all the coefficients are complex. We substitute these expressions into equations (2.134) to obtain the displacement fields and the stresses as a sum of complex power series. We now substitute these expressions into the system (2.130)-(2.133) and solve a recurrent system of equations to find the coefficients. The main relations between the coefficients are ttn+l

= /?n+3 = a n + 3 = 6 „ + i = 0 , 71 = 1, 2 . . . ,

0-2 =

0,

/3 2 =

0,

b0 -

XQCLQ =

0.

Thus, by solving the system (2.130)-(2.133) we obtain a 4 x 4 linear algebraic system for the coefficients a.\, fa, 03, b\, and a 2 x 2 system for the coefficients Pi,a\. As a consequence, the complex potentials have then the following form: h —, <j>0(z) = a0+ aiz + a3z3, i^0{z) = b0 + b\z. z° (2.137) Here we write the constants: _ /Jo(2/ifl0 + (A; + 2/Qfli)[(A - An)(ci + c2 + c3) + (M ~ A»Q)(CI + <%)] 4fifi0Ro + (A* + 2fi*)R1(x0fi + fj,0- (fi- (j,0)) (j>(z) = — , tp(z) = z z

2/x/xOJR0[A(ci + c2 + c3) + /i(ci + c2)] 4/i/i0i?o + (AJ + 2fi*0)Ri(x0fj, + ix0 - (fi - Ho))' 01 = i ? j ( 2 a i - ( A - A0)(ci + c 2 + c3) - ( / i - / i 0 ) ( c i + c 2 )), "l =

:—Rl(fJ. - Ho)(ci - c 2 - v ^ i c 4 ) , a 3 =/3 3 i2f 6 - a i - R f 4 , X/X0 + /X

#3 = « ! a i - x 0 (3 H I

— Ro

Rx) 4/x/z0

Rx] R0

Afifi0

Imperfect interface.

"Coated" conical

inclusion.

99

: (ai + fJ.Rl(c2 - ci - i\Z2c4)) 4ai 3/3, yh = -52- _ 3 T + (^ - Mo)(c2 - ci + iV2c 4 ).

(2.138)

Therefore, the problem for the plane strain for the first two components of the functions w^\ w0^ has been solved. The displacements wr ,w\p' can be evaluated using (2.134). Since we are interested in the behaviour of these functions at infinity, we consider the asymptotics shown in Section 2.1 (see (2.23)), and write them in the cylindrical system of coordinates. From here, we equate the coefficients of order 0(l/r) of wi- ,w\p and the asymptotics at infinity. We first write the vectors present in (2.23) in the cylindrical coordinates. Thus, we have /_£cos2^+2!Eii£\ r

(1

W >(^)r«) = A ( rW(£))=2 9

(

w ( 2 ) ( | ) r « ) = ^(r( 2 )(0) = 2g

r

\-x

-i

r

sin tp cos
sin ip +

l-x

>

i*\ (2.139)

sin

\

/

w(3, r

# <«=^<4 r<1,K)+ 4 r<2,( «> /

= V2q

V

l+x

sin 2(p \ (2.140)

-^COs2(£

/

We consider the linear combination given by (2.23) for the vectors W{i)(£) and equate the coefficients in the expansion (2.23) and the displacement field (2.134).

100

Dipole tensors in spectral problems of elasticity

Thus, t h e coefficients af'

are given by

nW

- „(2) _

Cl-i

—

(Jen

^ i ( M ~ Mo)

4q(xfi0 + n)

Rl[(X*0 + 2/x 0 )#i(x 0 - 1)(A - AQ + xx - xxQ) + 4xxofl0(A + xx)] 4g(x - l)[4/xiXo#o + (AS + 2n*0)R1(x0n + 2/x0 - /x)] ,(2) 1

=

a (i)

2

=

Ri(ti-l*o)

4g(x/x0 + /x)

iff [(A; + 2/x0)iZi(*o - 1)(A - Aa + n - /i0) + 4/i0.Ro(A + /*)] 4g(x - l)[4/Jiz0.Ro + (A* + 2/x*)fli(xo/x + 2/xD - /x)] v<3) - J?)

R\ 4g(x-l)

-

a (i)

a3

(A* + 2 M *)i?i(x 0 - 1)(A - A0) + 4/x0A/i!o AfifioR0 + (A* + 2/x*)/?i(x0/x + 2/x0 - /x)

_ a (2) _ a (3) _ o a ffl -a3 -a3 - U, a3 -

^

~ PQ)

2g(x/Xo+/i)

-

foul) U-141J

Thus, we have obtained the coefficients characterising the behaviour at infinity of the first two components of the function w^1'. We shall now analyse the problem for the third component of the displacement w^\ Out-of-plane shear problem We consider the problem for the functions w3 '(£),w3

{£):

A^3o(1)(£) = 0, 11(11 < Rlt A ^ K ) = 0, 11(11 > Ru (J.—^—(Ri,
= -V2(fi-

fi0)(c5 simp+ c6 cos if),

dw(1) pi 3 {Ri,
+ ^{41)(Ri,
^e[0,27r).

(2.142)

Imperfect interface.

"Coated" conical inclusion.

101

We take the solution in the form «£> = c5V<5>(0 + <%V<>6\£), w°3{1) = c5V°'(5>(() + c6V°^(t),

(2.143)

where V°'( 5 )((), V°'( 6 )((), and V^(£),V( 6 H€) are harmonic functions in {||(|| < Rx} and R 2 \ {||(|| < i?i}, respectively, and V&{$), V<6>(£) have the following asymptotics as ||(|| —» oo:

v<5> ~ a f ^ 4 ) ( | ) r ( 4 ) + 4 5 ) ^ ( 5 ) (|)r(0 + --., V ( 6 ) ^ 4 6 ) W ( 4 ) ( ^ ) r ( ^ ) + a i 6 ) W ( 5 ) ( | ) r ( | ) + . . . , as | | ( | | ^ o o . (2.144) Using (2.143), (2.144), we reformulate (2.142) and write it as a set of two problems:

A?V°(5)(0 = 0, 11(11 < RU A^ 5 )(() = 0, 11(11 > RU dV^ H—^-(Ri,
dy o ( 5 ) -Ho

dr

r

(Ri,
/ i ^ - ^ i . y . ) = -^/isin^+g^5)^!,V)-V°(5)(iJi,¥»)),

V

G

[0,2TT),

(2.145) and A?V°<6>(() = 0, 11(11 < Ru A^6\0

av (6 > M-

fi^(RuV) or

or

av o ( 6 )

(i?l ,tp)-fJ,o —5

or

=

= 0, 11(11 > Rlf

(-Rl» V) = - V 2 (M - Mo) COS V?,

-V2»cos
Now, we know that

w (4) (i)r(() = -^rafran ll(ll) = - a f e ^ = - ^ £ , (2.147) (5)

w (£)r(() = - ^ 4 ( i n 11(11) = - a f e ^ = -g*.

Dipole tensors in spectral problems of elasticity

102

Thus, we write v°(5)=di6+^2, (2.148) V(5)

^3$!

d.4£2

Substituting these functions into the system of equations we obtain the coefficients d\, ^2,^3,^4, and therefore, the coefficients a 4 , a 4 ,a$ and

5

4

P

VMo-Ro+M^i(M + Mo)

4

5

(2.149) 2.2.2.3

Problem for

w^

Once we have solved the problem for the functions w°^l\w*^-\ it/ 1 ), we now formulate the problem for the next order terms in the asymptotic expansion of the displacement fields for each layer. We consider the secondorder terms of the boundary layer, e2w°(2\£), s2wW(£), and e2w*(2\(,(p) for the displacement fields. We take the solution in the form v0~&°(
11(11
+ w*W((,ip)+e2w*W((,
v ~ * ( ^ , 6) + ex(6)wW(£)

+ e2x(9)w(2\£),

Ce[0,J2o], ||(|| >R1+

(2.150) eR0.

where x(#) is the cut-off function mentioned in Section 2.1 (see (2.27)). We now apply the corresponding Lame operator (L°{\0,(j,0], L*[X*,n*], L[X, fi]) in each region, and take into account the second-order terms. We thus obtain £ > o ( 2 ) ( 0 + £i«> o(1) (£) = 0, 11(11 < Ru l*0w*W((;,
Ce[0,i2o]^6[0,27r),

£ 0 ™ ( 2 ) (£) + A t » ( 1 ) ( 0 = 0, 11(11 >R1+

(2.151)

eR0.

The operators £ 0 ,£i,£i have the form (2.16), and IgJl are given by (2.95), (2.96), respectively.

Imperfect interface.

"Coated" conical

inclusion.

103

Since we know the function w*^(£,
Z*tu*«

MK + ^W^M

+

^W^M

f^*(1)(v) (2.152) Now we can write the expression for

IQW*^:

'(A: + 2 M ;)|Uf)\ l*Qw*M

=

* d2

*(2)

* a2

*(2)

(2.153) /

therefore, solving the second equation in (2.151) is equivalent to solving the following system of equations:

(A; + 2f0){$*wf) + £ < % ) ) + i(AJ + M + W^b)

/AodC2

=0

.(2)

V" + %Wt(
(2.154) From (2.154) it follows that w*W is a quadratic function in C, and it can be written as

w*W = _F»C 2 + W*(2)MC + [T(2)(^)>

(2.155)

where W*(2) (ip), U*(2\
Dipole tensors in spectral problems of elasticity

104

Displacement boundary conditions We shall now analyse the displacement conditions at each boundary, retaining the notion of interface 1 and interface 2 given in the previous section. We consider the Taylor approximation for w^1' at R± + eRo given by (2.111). Because there is a term of order 0(e), we shall take into account that term for the second order in the asymptotic expansion for the displacement. We will also incorporate it in the conditions at each boundary. From the conditions (2.81), (2.110) and (2.154) we obtain: Interface 1:

= w^2\0)

w^iRup)

= U*{2\if), ip e

[0,2TT).

Interface 2:

w^(Ri


+eRo,v) +Ro-^r(Ri,

= RlF*&)

+ RoW<2\ip)

+ C/*(2)(V),

At the second interface we also consider the Taylor expansion for at i?i + eRo ft

(2.156) w(2\£)

(2)

™(2)CRi + £#o, f) = u>(2)CRi, v>) + eRo—^iRuip)

+ ...

(2.157)

Thus, we re-write the displacement conditions at the second interface as follows wW(R1,lp)

+ R0-^r(R1,
= R20F*(
=

w<2\R0,ip)

+ W
(2.158)

We want to find the function W*^2\tp). Subtracting the condition (2.158) at the second interface from the condition (2.156) at the first interface we obtain W& (Rl,

V)

- wo<2) {Rl ,
(Rl, y,)

= R20F*{
(2.159)

Imperfect interface.

"Coated" conical

inclusion.

105

Taking into account (2.113), we can then write W<2\v)

= J-[«,< 2 >](i2 1>v 0 + ^-{RiM

- RoF*(
[0,2TT).

(2.160) On the other hand, F*(
F'(
--1±ir[wWm,
-5^35^5 (l^-'T

<2 I61)

'

Finally, from (2.156) it follows that the function U*^2\ip) is equal to the function io°(2)(£) evaluated at ||£|| = R\. Therefore, we have written the functions that are present in the representation of the function w*(2\(,
o{1 J

B°0w°M(R1,cp)+B°1w°W(R1,
6

= J2cjy*(-j){v)

+ b*1w*(1\0,
where *0(1,3>(J2i,¥>) = -(A„ + 2no)£ • ve& = (A0 + 2/i0)fl1e<3>,

(2.162)

Dipole tensors in spectral problems of elasticity

106

*°( 1 ' 4 ) (i?i, ¥ )) = 0, *o(1>5)(#!,) = -V2LI0£

• ve^

= V2/xOJRie(2),

* o ( 1 ' 6 ) ( i ? i , ,

(2.163)

are the contributions from the function 3>° into the stress field for the inclusion, while the functions ^*^\u) are the contributions of 3>* for the stress field for the coating layer. They have the same form as those shown in (2.119), (2.122), but with elastic constants A*,/x*. Interface 2:

Bow^^)(R1,^)+B1wW(R1,
^^(Ruf) j=i

6

= ^ C j * * « ( i / ) + 6 ^ * ( 1 ) ( ^ o , v ) +b*0w*(2\Ro,
(2.164)

where

^•3\RUip)

= -(X + 2A*)€ • " e ( 2 ) = (A + 2/i)i? ie ( 2 ), (2.165)

4

6

2)

¥& >(/2i,¥>) = 0, ¥& >(i2i,¥>) = - V 2 / x | • i/eW = V2/xflie( ,

We now combine the two stress conditions (2.162), (2.163). Within the coating layer, the term Ylj=i cj^* (u) does not depend on £ and is present in both conditions. Thus, (2.162) and (2.164) give

BoWV\Ru
-blw*W(Ro,
- b*0w*W(Ro,ip) = BZw°V>{R1,ip) + B01w°W(R1,
+ J2cj^°{1'j)(Ri,'p)-b*1w<1\0,lp)-b*ow*^(0,ip), 3= 1

tpe

[0,2TT).

(2.166)

Imperfect interface.

"Coated" conical

inclusion.

107

We can write the last equation as follows *W 2 >(fli,¥>) - B°0w°W(Ru
+ Y,cJ*{1J)(Ri,
d_ - Ro^Bow^iRuv)) ' dr'

-

+

Z W

1

^ , ^

blw<1\Ro,Lp)

- 6 X ( 1 ) ( 0 , ^ ) + 6>*(2)(i?o^)-b>*(2)(0,
(2.167)

where

J2*{1'j)(Ri,) - *{n\'j)(Ri,
0= 1

Evaluating b*0w*W(R0,ip) - b;$w>*(2)(0,
bZw<2\Ro,
&[41)](*i,v)

(2.168)

V f [wPiR!,?) ) On the other hand, 6Iw*<1>(flo,¥>)-&!«>*(1)(0,¥0

/ ~K\Wf\{R,M

f -A^{[4 1 >](i2 1 ) V )} \

\

+ Ri

-Ro

V

o

j

-^{[^(Ruf)}

.

0

\

Thus, we can re-write (2.167) as follows Bow^(R1,)

=

d -RofriBowMKRutp)

-(B1«;«(i?l¥p)-B>0«(i?1,V)) + ^Cj*(1^(i?1,¥))

(2.169)

Dipole tensors in spectral problems of elasticity

108

n^htn. ,„\\ /2[w^](R lt
2[w$)]{R1,
+ Ri \

„(i)

/ . , * d L„(l)l

+ R~i

]{Ri,
(2.170)

K&v^KRi,*)

V

o

J

We now re-write the condition for the jump in the displacement. From the condition in (2.164), we shall calculate blw*(2\Ro,(p). The latter can be written as:

( (XI + 2fi)(2RoFZ(
ti(2RoF;{
(2.171)

We re-write the condition (2.164) at the second interface using (2.171), (2.160) and the expression for b{w*(1\R0,(p). This yields

B0w^(R1,lp)

=

B1w^{R1,
((Xt + 2f0){£[w?)}(R1,
+ RoFZ^)} \

»:{±jwr2)}(Ru
6

6

(2.172) 3=1

3=1

Therefore, we have now combined the stress and displacement conditions at the boundaries and obtained a system of two equations for the two unknown functions w^ and w°^: £o«> (2) + A » ( 1 ) = 0, ||£|| > Ri, C°0w°W + c°w°W with the interface conditions (2.170) and (2.172).

= 0, 11(11 < Ru (2.173)

Imperfect interface.

2.2.2.4

"Coated" conical

inclusion.

109

Asymptotic behaviour of w(2> at infinity

The function w^ oo:

admits the following asymptotic representation as ||£|| —•

« ; ( 2 ) ( C ) = T P ) ( € ) + 0(||«||- 1 ) (2.174) 1

= a r « ) + b + Efa) + OflKir ), as ||£|| -» oo, where d, 5 are constant vectors. To evaluate a we use the same procedure as that of Section 2.1. We consider the dot product of (2.173) and the unit vector eW and integrate it over a circle of radius R. We evaluate the integrals by parts and use the conditions (2.170), (2.172). Then we consider the limit as R —> oo. This yields 0= /

eW • (C0wM (£) + £lWW

(£))d£

JDR\g

= f

eW

+ [e^-{Bo0w°M($)

• (B 0 u> (2) (£) + BlU>W(£))dZ

+ Bo1w°W(Z))dl + 2Ii, 1 = 1,2,3,

(2.175)

where Ij = — /

£JU>3

K

'dl + fi /

i^«4
dl, j = 1,2,

Jdg

JDR

-Xo f {viwl{l)

+v2w°2{1))dl,

Jdg

where v\, V2 are the components of the normal v.

(2.176)

110

Dipole tensors in spectral problems of elasticity

We re-write (2.175) as follows: e « • (B 0 ™ (2) (£) + B i i u « ( £ ) - J3°0w°W(Z) - B?u; 0 «(£))dZ

0= / Jdg

+ [ e^.(B0wM(Z) JdDR

+ B1wW{£))dl

+ 2Ii, i = 1,2,3.

(2.177)

The first integral on the right-hand side of (2.177) can be evaluated using the interface condition (2.170). The latter yields d

Ra-{B0w^){RlM^Y,c^i\Rx^)

,(*).

0: Jda

i=l

,(Di

dl

o + [

e®.(B0w<-2\t)

+ B1w(1\t))dl

+ 2Ii, i = l , 2 , 3 .

(2.178)

In order to evaluate the second integral in (2.178), we first consider the asymptotic at infinity of w(2\£) given by (2.174) and of u / 1 ) ^ ) , given in Section 2.1 (see (2.22)). The integrals relating the stress operators BQ,B\ acting on *&' ' , E , respectively, have been evaluated before in Section 2.1 (see (2.51) and (2.54)). Combining these two expressions gives e(i).(g1T(i)+B03)^

x-2 x

/ .dDR

L

e(2) . ( B l T (D + BoS)dl =

^_?rf,

dDR

*

f e^ . (Bj Y(1> + B0S)dl = JdDR V ((„.(JX) c ^ +• QJX) ^ )+ e r f A+M

(6)

-ce,a\

2TT/X(1

- x)(i/ +

Au)

+ 4 2 ) ) + c 3 (af ) + a f ) ) .

(2.179)

Imperfect interface.

"Coated" conical

inclusion.

Ill

We shall next calculate the Ij integrals. First, we consider the expressions for u>3 ', u>3 ': (5) .

in

(6)

Qr sinw

a\

Z7r/i

27T/X

r

cos(p r

(6)

+ce

^lr+v^^cos^

(2 180)

-

Substituting these expressions into the representations for the integrals h,I2 yields ^ c e ^ a f + ^ O u - Z v K l ? ? ] , I2 = c^a^

+ V2(fx-^nRl}.

(2.181)

To evaluate the integral Is, we consider the following identity: (!) ,

•

(1)

cos
(1)

=w).',

which implies v^wp + v2w{2] = ~wrl)

on

%

(2.182)

The minus sign on the right-hand side is due to the fact that v is the inward normal vector on dg. Thus, I3 = X f

w^dl

JdDR

-X

f Jdg

w^dl

w°{1)dl.

+ \0 f

(2.183)

Jdg

From (2.137), it follows that the radial component of the displacement field in" has the form: < ( 1 ) (r ) ¥ >) = - ^ - [ ( x 0 - l ) a 1 r + (x 0 -3)r- 3 (i?e{a 3 }cos2^ -Im{a3}sm2
(2.184)

and therefore, / Jdg

w0r^dl = TLR?(X 0 - 1 ) ^ . Vo

(2.185)

Dipole tensors in spectral problems of elasticity

112

Here, the constant a\ is given by (2.138). Now, we consider wT '(Ri,
±[^(Re{a1}coS2
+

Im{a1}sm2
-^j(Re{f33}

cos2ip + Im{f33} sm2
Thus, (2.187) Jda Idg

M

Therefore, from (2.183), (2.185) and (2.187) we obtain: (2.188)

•^3 = — (x0 - l)7ri?Jai. Mo

We have calculated the Ij integrals. Then we shall evaluate Jg S&'• 'J'dl, keeping in mind that £ • v = — R\:

f I>* ( 1 J 3 {Ri,
^0)2TTRIC5, -V2{H

+ c2)(A - A0) + c3(A + 2/x - A0 - 2/x0)])T.

-

/X 0 )2TT^C 6 ,

(2.189)

We now analyse the remaining integrals in (2.178). We will show that

j

&''

e^-{-Ro-^(B -\-Ro 0wW)(Ruip)

Idg

, • 2[wW]{Ru
2

+

* l KK M * ](/2i,v) ;

{ ti£[*>PKRi,d

J_ r,„(i)i

V

0

/

(2.190) First, we consider the components of w^\ w°^\ given by (2.180), (2.184), (2.186). For the first two components, taking into account the equalities (2.124), (2.125), we deduce that

Imperfect interface.

"Coated" conical

inclusion.

113

If we write this vector in the Cartesian coordinates, differentiate it with respect to r and integrate along 8DR, we shall obtain for the first two components integrals of the type

J0

* \ sin2

J0

* \ sm2ip J

J0

\ simp J

but all these integrals are zero. Therefore, f2* d i \ I eW • -^ \B0wW) (Ri,
(2.191)

For the third component, using (2.180), we have a „

,

„

W _i? oe (3) . (—BowW{R1 ltV ))

(5)

r

„

„

=

d2

(i)

^ - ^ - ( f l ^ )

.

(6)

a^sinyj

a^cos^

Thus,

iao

; ( 3 ) • —(B 0 to ( 1 ) )(i2i, v)«fl = 0.

(2.193)

The remaining terms in (2.190) involve the jump in the displacement across the interface, evaluated at r = R\. All the functions that are present in those two vectors are of the type {sin2y>, cos2<^}. By the same argument as explained in (2.191) (once they have been expressed in Cartesian coordinates), the remaining two terms in (2.190) are equal to zero. We now determine the components of the vector a. From (2.170), taking into account (2.190), (2.193), we have:

*i = I -'dff

eU)

•J2ci*™J)(Ri>^dl j=l

+ I

eU)

• (B°H + 8 i T ( 1 ) ) ^

JdDR

+2lj, j = 1,2,3.

(2.194)

114

Dipole tensors in spectral problems of elasticity

Thus, 4//

(6)

.

4/x

(6)

+ a<2>) + c3(a^

as = - y ^ - I c i C a W + <Jj») + c2(a?

+ a<8>)]

A + /i

4A ° -Tr/ijai - 2nR21[(\ - A 0 )( Cl + c2 + c3) + 2(/i - /i 0 )c 3 ]. A + /x0

(2.195)

,(J) We obtain the relevant constants p£' if we write the components of d in the form

6

ak = Y,CjPk)> * = 1,2,3; 3= 1

then the non-zero coefficients are ^

A + 3/z

4

2

A + 3/x

5

3

A + 2/T *

2

;

^ (A + n - A0 - HO)(H0(2HRQ + (A; + 2/x;)i?i) - 2(A + riwoRp , *• 4/x/i0fio + (A* + 2fi*0)Ri (x0fi + fa - (/i - n0))

-2nRl(X - A0) + - i ^ - T r i i ? , j - 1,2,

^3) = - A T ^ 3 ) + a 2 3 ) ) _ 2nRi{x+" - A ° - Mo)+ ^rk 7 ^ „ r (A - Ao)(/xo(2/xfi0 + (A; + 2/x;)fl!) - 2Xfiti0Ro X 4WoRo + (K + 2fJ,*0)R1(xofi + Ho - {ft - Ho)) >' Therefore, we have evaluated the components of the vector d.

Imperfect interface.

2.2.3

Stress

singularity

"Coated" conical

exponent

inclusion.

115

A2

The derivation of the eigenvalue problem for the stress singularity exponent A2 was done in Section 2.1 for the case of a conical cavity. In Section 2.1.3 we derived the corresponding boundary value problem for the function &2>((p) on the unit sphere S. The solvability condition for this problem is equivalent to the matrix eigenvalue problem (2.77), where the matrix M depends upon the coefficients of', pf . By solving the eigenvalue problem for M we obtain the stress singularity exponent A2 and the corresponding stress mode. We evaluated the coefficients or?' ,p£' in the previous section, and therefore, we can now write the corresponding eigenvalues of the matrix M. In this section we shall obtain the eigenvalues A2 and the associated eigenvectors. The matrix M has a block-diagonal structure, and is given by (2.71). Due to this structure there are three non-zero eigenvalues which are clearly identifiable, A2 , A2 , and A2 ', which are equal to M44, M55, M&Q, respectively. Also,

Therefore, taking into account the representation (2.71) of the matrix M, we have M12 = M 2 i, M i 3 = M 2 3 , M31 = M 3 2 , M11 = M 2 2 ,

(2.197)

and therefore, in order to obtain the remaining three eigenvalues, we need to solve the eigenvalue problem for the following 3 x 3 matrix: / M u Mia M13 \ M12 M n M13 • \ M 3 i M31 M 3 3 /

(2.198)

The eigenvalues of this matrix are 1,., ,, ., , 1 A2 ' = 2 ( M H + M 12 + M 33) + 5 V W l l + M12 - M 3 3 ) 2 + 8M13M31, A22) = \(Mn

+ M12 + M33) - \y/{Mu

+ Mi 2 - M 3 3 ) 2 + 8M13M31,

A^3) = M n - Mi 2 . Note that A23) = A 2 4) .

(2.199)

116

Dipole tensors in spectral problems of elasticity

We have seen part of the structure of the matrix M, and now we shall analyse the behaviour of its eigenvalues. We assume that the matrix, the inclusion and the coating layer materials have the same Poisson's ratio, that is, v = v0 = v*.

(2.200)

This relation allows us to write A =

2^_ 1 — 2i/

2 ^ . K 1 — 2f

=

W 1 — 2v

(2.201)

Therefore, all the eigenvalues will depend on the shear moduli /i, fi0, and AC We now consider (2.71) which defines the elements of M, the expressions for the eigenvalues (2.199), and relations (2.201) to calculate the eigenvalues. The eigenvalues are given by

(22o2>

w-WsW^^i *=m-m

+li±

-

^^f}

23

<->

where

/ i = (1 - v)^Ri(l

- /V/x)[—(1 + ") + ( ! " 2^)]

-^L(i-2v)R0[^(l

+

v)-l},

h = - ( 1 - 2u)R0 + (1 - v)^.Rx{^ + 1 - 2v), M M M

h = (1 - i / A ( l /x

MO/M)2#I

+ —(1 /x

MO/M)#O.

(2.204)

Imperfect interface.

"Coated" conical

inclusion.

117

From (2.204) we can see that (2.202), (2.203) depend on the ratios ^f and —, and (after re-arranging terms) ^ . The next eigenvalue is of multiplicity 2, that is,

w-^-Ww-

(2205)

Note that A2 > A2 ^° n o * depend on RQ or ^ . We can verify that when \i0 = 0 we recover the expression for a cavity. The following non-zero eigenvalue also has multiplicity 2: L(5) = A (6) = 2 2

5-2^-Si/2 fR0 + ^Ri(l-Ho/ri 4(1 - t/)(3 - 41/) ^ + ^ ( 1 + ^ ) '

which depends on ^ and ^-. We can easily verify that when Ro = 0 (no coating), this eigenvalue is the one corresponding to a perfectly bonded conical inclusion. 2.2.4

Some examples.

Discussion

and

conclusions.

In this section we analyse the eigenvalues for the imperfect interface which were evaluated in the previous section. The eigenvalues were evaluated under the assumption that all three materials have the same Poisson ratio. We study the effect of the coating on the eigenvalues, and therefore, we will analyse how A2 depend upon the ratio /x*//x keeping fJ,0/fi fixed. Due to (2.200), ti/n = Kl\

Mo/M = V A ,

(2.207)

which means we can write the eigenvalues as functions of /x,/i0,/x* and v, only. We shall assume that 0 < ^ < 10, 0 < — < 10. fj,

(2.208)

a

We consider the eigenvalues given by (2.202)-(2.206). The eigenvalues Aj , A2 , Aj , and Aj depend on the ratio /io/V, while the eigenvalues A 2 3) , A24) do not. It is important to note that for the "limit cases", we shall recover the eigenvalues we already know (for those cases). For instance, in the case when there is no coating (RQ = 0), we should obtain the same

Dipole tensors in spectral problems of elasticity

118

Fig. 2.8 Plots of the eigenvalue Aj , for the case when Ho/fi — 0.2,0.4,0.6,0.8, and Po/f1 = °- 5 i li l-5> 2> 2.5. The curve for the ideal contact (Bo = 0) is shown by a dotted line.

eigenvalue as those for a perfectly bonded circular inclusion. If we take Mo/M = 0>.Ro/-Ri = 0, then we will recover the eigenvalues for a circular cavity. We shall now consider the following cases: (1) (2) (3) (4)

Both coating and inclusion "softer" than matrix. Coating "softer" than matrix, and matrix "softer" than inclusion. Matrix "softer" than coating, and inclusion "softer" than matrix. Matrix "softer" than both coating and inclusion.

We proceed as follows: we will consider the set of values of \i0j{i = 0.2,0.4,0.6,0.8, when the inclusion is softer than the matrix, and the

Imperfect interface.

"Coated" conical

inclusion.

119

H>=2,R/R=1

0.1 ideal contact

0.05 M'D/(i=0.5

0 1»',/H=TT-

-0.05 t»' 0 'f"2

-0.1

/

M*a/(«2.5

0.1

0.2

0.3

> /

0.4

0.5

v

^=e,

^/^6,R 0 /R,=1

0.2

ideal contact

0.15 0.1 -

VRr1

0.2 ideal contact

/ --..../

(1*^=0.5

0.15 0.1 ~

0.05

<

0.05 0

M'n/n=1.5

-0.05

"

"

t»->=2

0.1

0.2

0.3

0.4

0.5

•

•

•

•

•

.

/

.

"

•

•

.

.

/

S^ ^~~

/ -0.1

•

MVM-0.5

-0.05

-0.1

"

~ 0.1

iFli^2

— 0.2

/

-P^-as 0.3

0.4

0.5

Fig. 2.9 Plots of the eigenvalue Aj , for the case when /io/A4 = 2 , 4 , 6 , 8 , and MS/M : 0.5,1,1.5, 2,2.5. The curve for the ideal contact (.Ro = 0) is shown by a dotted line.

other set of values of //<>/// = 2,4,6,8, when the matrix is softer than the inclusion. For every value of /x0//i we will plot the eigenvalue, taking /^//u = 0.5,1.0,1.5,2.0,2.5. In Figures 2.8 and 2.9 we plot Aj as a function of v for different values of n*0/H- We first consider the case when the inclusion is softer than the matrix and also plot the curve for a perfectly bonded inclusion for the same value of /X0/M- The eigenvalue A2 is positive for all considered cases. The curve for fi^/y. = 0.5 is always the closest to the dotted curve for the case of an ideal contact. In Fig. 2.9 we consider the case when the matrix is "softer" than the inclusion. The eigenvalue Ag is either positive or negative, depending on the ratio /i*//i 0 . The ideal contact curve for each case is positive and greater than Aj for the imperfect interface.

Dipole tensors in spectral problems of elasticity

120

u /U=0.4,R /R =1

M.o/|i=0.2,Ro/R,=1 0|»V„=0.5

-0.05 .

*

U'Jfl

ideal contact

M'o/H=1.5

ideal contact

-0.1

\

M'u/H=2.5

-0.15 > -0.2 -0.25 •

.if

0.1

*Xj 0.2

\

• / / '

0.3

0.4

-0.15 n'o/M=2.5

0.5

-0.2

*Ssy/I

/

"**"*>--^. 1,s

0.1

0.2

0.3

0.4

0.5

0.4

0.5

v H /u=0.6,Ro /R,=1 ^ o *^ 1

0.1

0.2

0.3

u Ai=0.8,R /R =1 r •(J

0.4

0.5

0.1

0

0.2

1

0.3

Fig. 2.10 Plots of the eigenvalue Aj , for the case when MO/M = 0.2,0.4,0.6,0.8, and MO/M = 0.5,1,1.5, 2, 2.5. The curve for the ideal contact (Ro = 0) is shown by a dotted line.

In Figures 2.10 and 2.11 we plot A^ \ First, we consider the case when /x 0 //i < 1, that is, the inclusion softer than the matrix. From Fig. 2.10 we see that the eigenvalue Aj is negative for all cases considered, and the strongest singularity is found for /i 0 //x = 0.2. The ideal contact curve in every case lies above the curves corresponding to the coated inclusion. In Fig. 2.11 we plot A^2) for the case of the matrix being "softer" than the inclusion. The eigenvalue A)> ' is negative for all the cases considered. The curve for the ideal contact is the lowest of all curves in each case and the strongest singularity is obtained for /U 0 /M = 8. The eigenvalue Aj does not depend on Ro or on \i*0jp. The plot for the eigenvalue A2 is shown in Fig. 2.12. We also show the graph for \i0 — 0, which corresponds to the case of a circular cavity. In Figures 2.13 and 2.14

Imperfect interface.

\l /H=2,R /R,=1

"Coated" conical inclusion.

121

u. Al=4,R /R =1

H /n=6,R /R,=1

n /u=8,R /R =1

n

^0 ^

0 ^

O

1

0

1

Fig. 2.11 Plots of the eigenvalue A^ , for the case when /lo/A4 = 2,4, 6,8, and li*0lp. = 0.5,1,1.5, 2, 2.5. The curve for the ideal contact (Ro = 0) is shown by a dotted line.

we plot the eigenvalue A2 . In the case when the inclusion is "softer" than the matrix (Fig. 2.13), the eigenvalue A2 is negative. The ideal contact curve lies above the curves for imperfectly bonded inclusions. In Fig. 2.14 we plot A25) for the case when the matrix is softer than the inclusion. In this section we formulated the problem for a "coated" conical inclusion, with a circular cross-section, embedded in an elastic matrix. We assumed that the elastic materials of the coating, inclusion, and surrounding matrix are homogeneous and isotropic, and have different elastic properties. The coating was taken to be thin and soft. We assumed perfect bonding on both interfaces, dk£ and dKe. In the analysis of the eigenvalues, we assumed that all three materials (i.e., coating, inclusion and surrounding matrix) had the same Poisson ratio,

Dipole tensors in spectral problems of elasticity

122

0

0.05

0.1

0.15

0.2

0.25

0.3

0.35

0.4

0.45

0.5

Fig. 2.12 Plot of the eigenvalue Aj ' = Aj , for the case when fJ,0/^ = 0.5,1,1.5,2, 2.5,3,3.5,4,4.5. The case for the circular cavity (notch) corresponds to the case when tx0/lj, = 0.

v, and we derived the representations for the eigenvalues in terms of v and the elastic constants //, /x0, and /i*. We plotted the eigenvalues for different values of the ratios (J.0/n and \i*0jii. For comparison, we also plotted the eigenvalues for a perfectly bonded inclusion. We analysed the effect of the coating on the stress singularity for different values of the ratio /i 0 //i. We have found that if the inclusion is "softer" than the matrix (/X0/M < 1); the soft coating "increases" the singularity (see Figures 2.10, 2.13 for A^2), A^5)). If the matrix is "softer" than the inclusion, then the coating "decreases" the singularity associated with A2 . In the case of Aj , which does not depend on the coating parameters, we found that for /i Q //i < 1 there will be a singularity, still less than the one for a cavity, while for Ho/fJ. > 1 there will be no singularity in the stress field.

Imperfect interface. "Coated" conical inclusion. H0/M>.2, FyR,=1

|i o /n=0.4

123 R

c/R,=1

•s^/ • „ / H U \ />:>*•<

/•.*•'5

. A*-! /fr>.2.5

v ( 5 ;) i (6) Fig. 2.13 Plots of the eigenvalue A^ = A£', for the case when /*0//i = 0.2,0.4, 0.6, 0.8, and MO/M — 0.5,1,1.5,2,2.5. The curve for the ideal contact (Ro = 0) is shown by a dotted line.

Finally, in t h e following table we summarise t h e results. We indicate t h e effect of t h e soft t h i n coating (compared t o t h e case of a perfectly bonded inclusion) on t h e stress singularity exponent for each eigenvalue considered in this section. Mo/M < 1

Mo/M > 1

A«

no singularity

increased

A<2>

increased

decreased

Af = A?

no effect

no effect

A ? > = A<6>

increased

increased

Dipole tensors in spectral problems of elasticity

124

0.6 ideal contact

0.2

•

1

W

^ = 4 ,

t\/H=2, R
ideaf contact

0.4

\

(i' o /(i=0.5

0

;...V---

/lixO.S

JI.*J»I

v7 ^ r -0.2

t>7n="

%«

~———-________^^

[iVtel.5

° M-0/M=2

-0.2

-0.4

0.1

0.2

0.3

0.4

0.5

Tji^S——..

-0.4

0.1

0.2

0.3

0.4

0.5

v

v Ho/M5, FVH1=1 1 0.8

ideal contact

.

.

.

.

•

\

0.6 •

.

.

.

>

•

•

-

"

"

'

ji" /ji=0.5

P?^ M/M.5

0 I»VM=2

-0.2 0.2

0.3

0.4

0.5

,'jr*r-

—.

-0.4

0.1

0.2

0.3

0.4

0.5

v I (6)-1, for the case when ^ O / M = 2,4,6,8, and Fig. 2.14 Plots of the eigenvalue Aj = A^" p.%/H = 0.5,1,1.5,2,2.5. The curve for the ideal contact (Ro = 0) is shown by dotted line.

Chapter 3

Multipole methods and homogenisation in two-dimensions

3.1

The method of Rayleigh for static problems

We consider an array of infinitely long circular cylinders, periodically spaced in two-dimensions, as shown in Figure 3.1. Each cylinder has radius a and possesses a transport property (such as, say, dielectric constant) which is different from the surrounding matrix. The field, whether it is electrostatic or elastic, can be represented by a scalar potential V. If the potential between the cylinders is labeled V, while the potential within the cylinders themselves is labeled V1, then in both regions the potential satisfies Laplace's equation: AV = 0

(3.1)

AV* = 0

(3.2)

in fi, and

in C. Here A is the two-dimensional Laplacian operator. On the edge of each cylinder we prescribe the boundary conditions V = Vi

(3.3) i

dV

dV

In this case a can denote the conductivity of the cylinders, in the case of electrostatics. The surrounding matrix material has been normalised so that its conductivity is equal to 1. 125

126

Multipole methods and homogenisation

Fig. 3.1

in

two-dimensions

The array of cylinders, in direct space.

Finally, we impose a potential gradient on the array of cylinders, in the direction of the x-axis. This can be expressed by boundary conditions which apply on the edge of the unit cell: V^,y)=V(~,y)

+ SVx,

(3.5)

V(x,^) = V(x,~) + SVy.

(3.6)

The derivatives of V are periodic in both the x and y directions.

3.1.1

The multipole

expansion

and effective

properties

If we take the centre of one of the cylinders as the origin of polar coordinates, then the potential external to the cylinders can be expanded in the series oo

oo

A

e

V = Yl eR (*') + ]C BeRe ( z ~0

(3-7)

The method of Rayleigh for static problems

127

where z = x+iy = re%e. We now split the applied field into two components, one which is odd in the a;-direction and even in y, and another which is odd in y and even in x. Bearing in mind that the inhomogeneous problem cannot exhibit symmetries which are not possessed by the driving potential, we can expand the potential function V as cosn# n odd oo

+ nEodd K(D" + B »(7) n ] s i n n *-

<3-8)

Here and henceforth we write the vector r in polar coordinates as the ordered pair r = (r, 9). Within the central cylinder the potential must be non-singular, so we can expand it as

oo

=

C

Q " ICn cosnfl + C°n sinnfl] .

o + E

(3.9)

n odd

where once again we have split the field into its even and odd components. Substituting (3.8) and (3.9) into the boundary conditions (3.3) and (3.4), an algebraic manipulation allows us to discard the coefficients C|'°, hence

where, once again, a is the radius of the cylinders. For brevity, it is convenient to frame this condition in terms of the 'conductivity contrast' v = ( l + o - ) / ( l -&), thus AT = vB?

.

(3.11)

In a paper written in 1892, Lord Rayleigh notes that the values of the coefficients Ai'°, Bl'°, A^'°, B^'", • • • are necessarily the same for each cylinder. The coefficient AQ however changes as one moves 'upstream' with the potential gradient. Without loss of generality, we set A% = 0 within the central cell.

Multipole methods and homogenisation

128

in

two-dimensions

Fig. 3.2 The central unit cell, showing the contour within which Green's theorem is to be applied.

We now apply Green's theorem to the potential V and a function U, which we define to be U = x = rcos#.

(3.12)

Choosing the contour to encompass the region between the central cylinder and the outer boundary of the unit cell (see Figure 3.2) we obtain / {VAU - UAV) dA=

[

(v

9U__dV_x U\ds dn dn

(3.13)

Both U and V satisfy Laplace's equation, hence the left-hand side of (3.13) vanishes and we are left with the line integrals around the outer boundary and around the central cylinder. Evaluating the integral around the circular path dC first, we obtain by direct substitution idC \\ JdC

dn

dn fl-K

C S6

Jo

+

(-)"

°

S

[(-)n (AnCOSne + An Sin n0)

n odd

(B„ cosn6 + B°nsinn6)

zos6 J2 n\(-Y

(A^ cos nO +

A^smne)

n odd

(~Y

{Ben cosn6 + B°n sinnO) ) add = 2iraBt

(3.14)

The method of Rayleigh for static problems

129

The integral around the outer boundary is meanwhile

a

on

on

rd/2

dx

J-d/2

~ y\x=d/2

c=-d/2

~~ V\x=-d/2j

dy (3.15)

The remaining integral on the right-hand side of this expression is equal to the total current, or flux, across the side of the unit cell in response to the applied potential. If we define d/2

gV

•d/2

dx

(sx

dy,

(3.16)

c

(3.17)

=-d/2

t h e n we find

a

v

r

ir \ on

u

ir)ds = on J

**d~6V*d

where SVX is the drop in potential from left to right. When we add in the contribution from around the cylindrical boundary, we obtain the expression Cxxd - 8Vxd + 2a-nB\ = 0 .

(3.18)

The equation (3.18) can now be re-arranged to give an expression for the effective conductivity of the central rectangle in the x direction: a

xx

-

Wx

=

l-

2TTOBI

d6Vx

(3.19)

Using exactly the same reasoning, the effective conductivity in the y direction is VV

d6Vy

(3.20)

The problem is now reduced to calculating the relationship between the dipole coefficients B\'° and the external gradient (6Vx,6Vy).

130

3.1.2

Multipole methods and homogenisation

Solution

to the static

in

two-dimensions

problem

For convenience in notation we introduce the direct lattice {RP}, which is the set of vectors in two dimensions, each of which points to the centre of the pth cylinder. For brevity we will say that p = 0 labels the central cylinder. Formally, we define Rp = (nd, md) , n, m e Z and p = (n, m) .

(3.21)

Much of the analysis which follows uses sums over functions in Fourier space; the vectors from the origin to the hth node of the reciprocal array are defined to be

(

27T

n—,m—

27r\

J , n, m € Z and h = (n,m) .

(3.22)

The subscript h in the vector {K-h} is a label similar to p in direct space; the vector K/j points to the centre of the hth cell in the reciprocal lattice, and, as with the direct lattice, h = 0 corresponds to the central lattice point in reciprocal space. The unit cell in reciprocal space is also a square, with side length 2n/d. We introduce the periodic Green's function for this problem as the solution of the equation AG(r;r')=£*(r-r'-.Rp)-±

(3.23)

p

where r and r' are vectors within the region fi and where A is the area of the unit cell. The constant term 1/A on the right-hand side of (3.23) removes the net 'charge' from the unit cell. This is necessary to avoid conditionally convergent terms in the expansion of the Green's function. We can express G as a sum over the reciprocal lattice

G{£) = Y,9{Kh)eiK*Z h

=

J29(Kh)eiK^+g(0)

(3.24)

h^iO

where £ = r — r'. The Poisson Summation Formula (see, for example, Jones 1966) relates sums over the direct lattice to sums over the reciprocal lattice via the equation

£*«--Rp) = ^ E e J i r f c ' * ' p

h

(3-25)

The method of Rayleigh for static

problems

131

and so (3.23) becomes

A

h^o

A

h

7 $>**-*.

(3.26)

Hence we have 9{Kh)

=

~l^

ioih

1 *—r

e^h'^

( 3 " 27 )

*°

and the Green's function is

MO

h

with g(0) being some constant which has no effect in subsequent field computations, and so can be ignored. Glasser (1974) obtains the exact closed form for G

xS-sr--(5i) ll+c - (,r),+ s ta2 1 ^ e

i K h

^

f Z\2„

_

_„_ / 0 ..M

, 1

h^O

^ > »

6\ (K£ sin 7 + in cos 7,3) [(9i(0,g)]V3

(3.29)

where q = e _7r , 7 = arg£ and 6i(z,q) is the elliptic Theta function of the first kind. The practical use of this representation is that the Theta functions are well tabulated and this ameliorates numerical construction of the Green's function. In addition, one can use (3.29) to obtain analytic expressions for a wide class of sums over the reciprocal lattice, a technique which we will employ later on. For problems involving arrays of circular cylinders, it is convenient to express the Green's function in terms of Bessel functions: 1

1

h^O

h

°°

t=-oo

=-E^7£ £=-00

h^O

{KhdY

132

Multipole methods and homogenisation

£

in

two-dimensions

iee-^SeA2(0

(3-30)

t=-oo

where we have defined

Fortunately these 'lattice sums' (3.31) have been studied by many authors (most notably by Ewald 1921). At the worst they can be summed directly, and in fact for many instances of the index I the sums can be expressed as a terminating polynomial in £. For a square array, we have by symmetry that Se,e,2{0 — 0 unless I is an integer multiple of 4, and also that 5_^_^2(0 = S(,e,2(0- The non-trivial sums can be evaluated by expanding (3.29) in powers of the argument of £. The ones which directly concern us are:

So,o^) = - ^ 4 1

|,+7o

+

1

p4inep

P¥=O

2TT

(3.32)

F

2n

where 70 « —0.318895593319827 is a constant and the quantities Se are the static lattice sums inBp

^n=EV P^0

K

(3 34)

"

P

originally introduced by Rayleigh. Substituting these results into (3.30) and neglecting such constants as UJQ we obtain the final expression for the static Green's function:

<™-**(h)-(h)'-•*£%("<««>)•

^

which is unique to within the addition of a constant. We show in Figure 3.3 a surface plot of the function G obtained using equation (3.29); the series in (3.35) has a radius of convergence equal to d.

The method of Rayleigh for static

Fig. 3.3 origin.

problems

133

Graph showing the static Green's function with the singularity placed at the

Applying Green's theorem within the unit cell, in the region fl shown in Figure 3.2, we have / / (VA'G - GA'V) dA' = f J Jo. Jrr u s e

™V-G^ dn'

dn'

ds'

(3.36)

where T and dC are the contours shown in Figure 3.5. We already know from our definition of the Green's function (3.23) that If

[VA'G - GA'V] dA' = V(r) - \ \ \

VdA' .

(3.37)

The second term on the right hand side can be set to zero without any loss of generality and so we obtain

V(r) = f TUdC

™V-G™ ds' . dn' dn'

(3.38)

Periodicity of the functions G and dV/dn' guarantees that

L

8V

(3.39)

and it is a straightforward matter to show that

L

dG

*rA

i

nr

r c o s

#

, rT/

rsinfl

(3.40)

Multipole methods and homogenisation

134

in

two-dimensions

where 6VX and 5Vy are the differences in the potential across the unit cell in the x and y directions respectively. Thus we have the functional form of the potential V(r)=5Vx.

—

+5Vy.

—

jdc

+

dr'

dr'

ds'.

(3.41)

We expand both the potential and its radial derivative as Fourier series on the boundary of the circular inclusion: .imO

(3.42)

= Yl P™eim$

(3.43)

V(r)\

dv dr

m = — oo oo

(r) r—a

m = — oo

The Fourier components am and f3m are related to the unknown coefficients in the full expansion (3.7) by the equations " 2 m - 1 = l^A\m-\ ft

-(2m-l)

ftm-1

P-(2m-\)

=

^ [ - A | m - 1 + B2m-l]

~ ^[A2m-1

2 2m-1 B 2m-li = [A-2m-1 2a 2m - 1 + 2ia K*2m-1

—

^

2a

B

2m-l]

(3.44)

+B2m-l]

(3.45)

+ #2m-l] + 7^[^2m-l +

[^2m-l

-°2m-l]

(3.46)

^2m-l] >

(3.47)

B

~

2m-l]

2m - 1 2ia [•^2m-l

—

with all the even coefficients being zero due to the symmetry of the array. We now expand the Green's function (3.35), choosing that r' < r: G(r;r')

= -lnr--Y,-

e

(j)

coe[/(« - V)]

- — (r2 + r'2 - 2rr' cos{9 - tp))

U=0m=0

'

\

(3.48)

/

)

The method of Rayleigh for static problems

135

where we have defined lattice sums ae to be (Se \0

=

Ol

if I = 4m , m € Z o1 otherwise

(3.49)

for ease of notation. The radial derivative of the Green's function can be written Bd

r'

1 .21 /r'\e

r

1

Re e e+m w_i m i x me i (-iy
e+m

(3.50)

l i=0 m=0 '

We are now in a position to evaluate the integrals around the boundary of the inclusion. The first of these appearing in (3.41) is

Jdc

Br

'

-l^ +

Jo 1

/r>\e

°°

v

e=i

^cosie-tp)

i

'

(-l)V<+nrnr"-1ein*e"v U=0n=0

v

E a«

0imifi

ad(p

z=0 (

OO

OO

= ^ EEn +^ e V( Tl^+ e \ a

n+er

The second integral in (3.41) is r2ir

( r 2 + r' 2 - 2 r r ' cos(6> - <£>))

_n„tAnO,

a e

ct-e

(3.51)

136

Multipole

methods

IL^=0 c—t\ „n— = n0

and homogenisation

'

\

E A-

in

two-dimensions

/

.tmip

ad
m = —oo

oo

2

+ii:e

n+ n +1 infl ra^e"'Q_\ i E E n^^ ^ ^ +e n

ma

.

(3.52)

Ln=01=0

Interchanging the coefficients am and 3m with the more familiar Am° and B^° by means of the equations (3.47), we obtain the functional form of the potential T

T

7T&

V(r) = SVX - cos 0 + SVy - sin 0 - — [B\r cos 0 + B°r sin 0] 271—1

OO

+ E

[ B a»-i cos(2n - 1)0 + B°n_x sin(2n - 1)0]

(;)

71=1 OO

f ^

OO

21-1

/2n + 2 l - 2 \ x

n=l^=1

, „ + 2 € - 2 f/ \n 2n—1

'

x [ 5 ^ _ x sin(2n - 1)0 - B\t_x cos(2n - 1)0] .

(3.53)

On comparison with the expansion for the potential (3.7) we obtain two systems of infinite linear equations, for n — 1,2,... lln-X + *n,l^a 2 Bi e +

^ ^

(2n + 2 l - 3 ) ! , a»,™ n2n+«-2Re Bs (2n-2)!(2^-l)!(J2n+2'-2a ""1 = ^ ^ (3.54) 7T

^2n-l + *n,l^a25f y " ^

(2n + 2 l - 3 ) ! fljB+M.2™ (2n-2)!(2£-l)!CT2"+2^2a

, i?2

'~1 "

a% „ ^ d ^ (3.55)

The method of Rayleigh for static

problems

137

These identities determine the solution of the problem uniquely, and can be given a physical interpretation: the non-singular part of the potential at the origin must be equal to the net effect of singular sources located elsewhere in the array. If one absorbs the dipole term into the sum by setting <72 = IT/A in the first instance and 02 = —n/A in the second, then one recovers precisely the identities due to Lord Rayleigh (1892), the first being associated with an applied field along the £-axis and the second with an applied field oriented along the y-axis. If we concentrate firstly on the field applied along the a;-axis, then the relations (3.54) constitute an infinite linear algebraic system which links the multipole coefficients A\ and B^. If we ignore all coefficients higher than dipoles, then we obtain a first-order approximation to the system: 2

A\ + ^-B{

« -d5Vx

(3.56)

If we substitute the equation for the boundary condition (3.11), then we obtain {v + f)B\

= -5Vx + 0{f) (3.57) a where / = 7ca2/A is the filling fraction of the cylinders and v is the dielectric contrast. This is enough to determine a first order approximation for the effective conductivity: in conjunction with equation (3.19) we have efx = l-~r}+0{f) =

(3.58) (3 59)

VT~f+°^

-

This is the same result deduced by Lorentz (1952) and by Lorenz (1869). We note that the same formula has been discovered independently by researchers such as Clausius, Mossotti and J.C.Maxwell-Garnett. The treatment given by Rayleigh also allows the possibility of deriving correction terms for inclusions which have a higher filling fraction. This would involve including higher order terms in the system (3.54). If we include the quadrupole terms then we obtain the two equations Al + fBt + a^Bt A% + 3a4a4Bt

« °j5Vx « 0.

(3.60)

138

Multipole methods and homogenisation

in

two-dimensions

Using the boundary condition (3.11) to eliminate A\ and A%, leads to the approximation Bi

*/ + / - ^ ( < r 4 a 4 ) 2

-6VX + O (f) d

.

(3.61)

The next approximation to the effective conductivity is then

The lattice sum can be evaluated either directly or by expansion of the theta function in (3.29). The result, given to 13 decimal places, is 04 = 3.1512120021539. This gives a correction term which is directly dependent on the filling fraction / of the inclusions. It is easy to see that this process can be continued as long as necessary in order to achieve accuracy to an arbitrary order.

3.2

The spectral problem

We now present a generalization of the method given in the previous section to dynamic problems. The physical principle behind the method is the same, relying on an identity between the singular and non-singular parts of an expansion of a potential function: the non-singular part of the potential around the central cylinder must be equal to the superposed effect of the singular sources arising from all the other cylinders in the array. As in the static case, we formulate the problem in terms of an integral equation involving a Green's function which has sources at all the lattice points in the array. We then expand both the potential and the Green's function in terms of basis functions which are appropriate to the geometry of the problem. Since the cylinders which we consider are circular, we expand the potential in terms of Bessel functions rather than in a Laurent series. We then project these expansions back onto the surface of the cylinder, applying the boundary conditions in order to solve the integral equation. The derivation given here follows that given by McPhedran et al. (1997), having been developed in a series of papers (McPhedran & Dawes 1992, Nicorovici & McPhedran 1994, Nicorovici et al. 1994, 1995a, 1995b, 1995c, McPhedran & Movchan 1994, Movchan et al. 1997). Most of the essential points have been compiled from these references; a few of the intermediary

The spectral problem

139

steps and comments which are necessary to make the procedure clearer to the reader who may not be familiar with the subject have also been added. 3.2.1

Formulation

and Bloch

waves

We consider the case of waves moving in an infinite square array of cylinders in two dimensions, the periodicity of which is of length d. Each cylinder has radius a and possesses a transport property (such as, say, refractive index) which is different from the surrounding matrix. If we assume that the wave is time-harmonic, then it may be described at each point by a scalar potential u, which satisfies the Helmholtz equation

(A + n 2 fc 2 )u i (r) = 0,

(3.63)

within the central cylinder, and (A + A:2) u(r) = 0,

(3.64)

in the region between the cylinders. Here n is the relevant transport property for the wave, such as the refractive index in the context of electromagnetism. For the case of anti-plane shear elastic waves, n = \fn/p where /i is the shear Lame coefficient and p is the density of the material. In all cases we assume that we have normalised the transport properties relative to the background material. We now assume that on the boundary of each cylinder the following hold: u = u\ du 1 dul dr n 2 dr

(3.65) . .

This is consistent with the boundary conditions which arise from continuity of field components across the cylinder interface in the case of electromagnetism, and with the continuity of traction in the case of elasticity. Note that when n —> oo the problem becomes singularly perturbed; this is an issue which will be discussed in Section 3.3. For the moment we can assume that n is finite.

140

Multipole methods and homogenisation

in

two-dimensions

As in the static case, we will find it convenient to work with both direct and Fourier lattices. The array of cylinders is again described by a set of lattice vectors { R p } , with p = 0 labeling the central cylinder. The unit cell is once again a square of side length d centred on the origin. In order to solve the problem completely we must specify boundary conditions to be satisfied on the edge of the unit cell. In order to find these, we note that because the potential u is a field component in a periodic medium then it must satisfy a periodicity condition, known as the Bloch or Floquet condition. This is written u(r + R P ) = u(r) e ik °- R * ,

(3.67)

where ko is the Bloch wavevector, which lies in the x-y plane and characterises the wave which is propagating through the material. Its origin in the field of Solid State Physics means that ko is often referred to as the crystal momentum. Functions which satisfy this kind of periodicity condition are often known in the literature as 'quasi-periodic' functions. Because the Bloch condition (3.67) applies to the value of the potential function over the entirety of the lattice, it also applies to its Cartesian derivatives. For this reason, it supplies both of the boundary conditions required on the edge of the unit cell. The relationship between the bloch vector fco and the frequency A; of a propagating wave is known as a dispersion relation. The slope at any point on the dispersion curve defines the group velocity of the wave. Hence in the frequency domain where the dispersion relation is 'flat', the group velocity is zero and no energy is transmitted by the wave as it moves through the lattice. One can also observe the phenomenon of band-gaps in the material. These are domains of frequency for which no propagating modes are possible. Any wave of this frequency would be heavily damped immediately upon entering the material. In the limit when the wavelength in the material is long and the frequency is low (i.e. when both fc and fco are small parameters) then the dispersion relation can be used to define an effective phase refractive index for the material. By homogenising the material in this way any effects arising from the boundary of the material can be ignored. If the change in phase of a propagating mode across the unit cell is denoted A $ = fco^, then the effective phase refractive index neff is defined by the equation A $ = hod — neffkd

(3.68)

The spectral problem

141

and so neff

—

.. dk~ hm -77fc,fc0-+o dk

= (3.69) a where a is the slope of the lowest frequency mode in the dispersion diagram as the frequency of the wave tends towards zero. 3.2.2

The dynamic

multipole

method

We begin by expanding the potential function u in terms of a set of basis functions (or multipoles) which fit the geometry of the problem. In cylindrical polar coordinates the Helmholtz equation (3.63) separates in terms of Bessel functions, and so we can expand u within the unit cell in terms of its singular and non-singular parts: oo

u(r,6)=

^

[aeJe{kr) + beYe(kr)}exp(i£9),

(3.70)

f=-oo

between the cylinders, and oo

^(^0)=

^2

ceJe(nkr)exp(ie6),

(3.71)

^=-oo

within the central cylinder, where only non-singular terms can occur. By applying the boundary condition (3.65) we can eliminate the coefficients ce from the expression for the potential:

=

aiJt(ka) + b(Jt(ka) J((nka)

From the remaining boundary condition (3.66) we obtain the relationship

ae = -Mebe

,

where M

=

nJe(nka)Y;(ka) nJe(nka)J'e(ka)

J^nka)Ye(ka) — J'e(nka)Je(ka)

(3.73)

142

Multipole methods and homogenisation

in

two-dimensions

The quantities Mi will, in general, be referred to as the 'boundary condition terms' or the 'boundary coefficients', for obvious reasons. From (3.74) it can be seen directly that Me. = M-e. We would now like to incorporate the effect of the other inclusions in the array. To do this, it is best to make use of a Green's function which obeys the same type of periodicity condition as the function u itself, i.e. the Green's function must be quasiperiodic. This Green's function will satisfy the differential equation (A +fc2)g(r- r') = £ ) 6{r - r' -

flp)eifc°-

(3.75)

p

where r and r' are vectors in the region £1 shown in Figure 3.5 and the operator A applies to the unprimed variables. The Green's function has been defined so as to automatically satisfy the quasiperiodicity condition g(r + Rp- r1) = g(r; r')eik°-R'

,

(3.76)

as well as a conjugate condition on its second variable, Rp) = g(r;r')e-ik°R*

g(r;r'+

.

(3.77)

It is a useful observation that we can immediately write down a solution for the Green's function: it is the sum of an infinite set of outgoing waves, spreading out from each point of the lattice. Thus, g(r;r') = -l-J2^l)(k\r~r'-Rp\)eik°R'>

.

(3.78)

p

The task is first to obtain an expansion of the expression (3.78) in terms of the appropriate functions; this will enable the Green's function to mesh cleanly with the expansion of the potential (3.70). Defining £ = r - r', we note that |i? p | > |£| for all p ^ {0,0}, and so in this region we can use Graf's addition theorem (see Abramowitz & Stegun 1972) to expand the Hankel function in (3.78): oo

Ho^im-Rpl)^

E l=-oo

HtMikRJJtikQeW'-i)

(3.79)

The spectral problem

143

where 7 = arg£ and <j>p = argJ2 p . Hence, omitting the central term,

£#o ( 1 ) (fc|£ -

Rp\)eik°-R>

p/0

,-H-r 12 [HtW(kRp)eit+'eik'>-R'] Ji{K)e~

= S

e=-ocp^£0

= St(k,ko)Je{kt)e-uT

,

(3.80)

where = '%2HiW(kRp)eit+>eiko-R'.

St(k,k0)

(3.81)

p^O

Thus we can express the Green's function in terms of Bessel functions: 00

l

W

g(r;r') = - -H0 (kO

~\Y.

^(fc,fc0)JK^e^7 .

(3.82)

The radius of convergence of this expression is determined by the limit of applicability of Graf's addition theorem. In this case, the formula (3.82) will converge whenever |£| < Rp for all p, that is, whenever £ < d. 3.2.3

The dynamic

lattice

sums

The task now becomes one of finding a more effective expression of the lattice sums appearing in formula (3.81). As expressed over the direct lattice, the sum converges very slowly, in fact the terms in the sum are -I

try

of the order O {Rp) "'. Ewald (1921) noted that sums which converge slowly over the direct lattice may converge much quicker if expressed as a sum in reciprocal space. To this end, we employ the reciprocal lattice defined earlier in (3.22): Kh = — (m, n)

m,neZ

(3.83)

The reciprocal lattice vectors, with the Bloch wavevector ko, are shown in Figure 3.4. One way of computing quickly converging expressions for the lattice sums is to examine the form of the Green's function when expressed as a

144

Multipole methods and homogenisation

•

\

w

\

_y

two-dimensions

•

•

•

•

•

•

\ .

•

in

Kh\

•

Fig. 3.4

The reciprocal lattice.

sum in reciprocal space. This is easily calculated if we start with the generic expansion g(^) = Y,9(QhyQA

(3-84)

h

where Qh — Kh + fco- We can now employ the incredibly useful Poisson Summation Formula to obtain a connection between sums in reciprocal space to their counterparts in direct space:

V] 6(£ - Rp)eikoR" P

= ^ V e^S A

( 3 . 85 )

h

By substituting this last expression into the Helmholtz equation, (3.84) becomes

£ ( - Q » 2 + k*)g{QhyQ^ h

= jY,jQ^ h

.

(3.86)

The spectral problem

145

Hence we obtain the spectral domain form of the Green's function 1 v-^

e'^ft'^

We now expand the relevant quantities in the spectral domain representation in terms of Bessel functions. Thus we find oo

eiQA =

£

i'JtiQhOeW*-^ ,

(3.88)

£=-oo

and so

e=-oo

h

^h

K

One can then formally equate the two representations of the Green's function (3.82) and (3.89): OO

^*=-oo

h

Vh

-K

By equating the powers of 7 in (3.90) and rearranging, we obtain absolutely convergent expressions for the lattice sums Se(k, ko)Jt(kO

= -H^\ki)6tfi

- A.*" £

^ % e

i i 9 h

• (3.91)

We can further simplify this expression by splitting the lattice sums into two parts, corresponding to sums over Ji and Ye Bessel functions respectively. Thus, Se = Sj + iSj, where

5/(fc,fc0) = YJJ^kRp)eU4'P^ko'R''

'

(3'92)

SY(k,k0) = Y,Y*(kRP)eit+pJko-R'

.

(3.93)

pjto

Multipole methods and homogenisation

146

in

two-dimensions

In order to evaluate the lattice sums S / , we again use a form of Poisson's summation formula £

g-ii^.^-fco)

=

( 2 J ! J- 6(ks -fco- Kh)

p

,

(3.94)

h

and set the magnitude of the vectorfcsequal to k and its argument equal to some variable 6S. Noting that within the first Brillouin zone ks—ko^= Kh for any h, we have ^e-i(ks-k0)Rp

(395)

=Q

p

We then use the expansion oo

e-ik3Rp

^

=

(-ifj^klQe^^-8^ ,

(3.96)

i=-oo

and substitute into (3.95) to find oo

]T ]T (-i)tJt(kRp)eit^*'-e^eiko-R'

= -1 .

(3.97)

p#0«=-oo

Hence we discover the identity oo

5 3 {-i)eS}!{k,ko)e-ue> = -1 .

(3.98)

f=-oo

By integrating over the dummy variable 6S we then obtain Sj(k,fco)= Se,o •

(3.99)

If we substitute this expression into (3.82) then we find that the lattice sums 5/make no contribution at all*; the Green's function can now be written 1

g{r. r') = _-y0(fc£)

1 ° °

~-J2 # ( * . k0)Jt{ki)e-^

,

(3.100)

«=-oo

*One viewpoint on this is that we need only have included the singular Bessel functions Y in (3.82).

The spectral problem

147

where, from (3.90), the remaining lattice sums are

Sj(k, k0)Je(H) = -Y0(H)Se,0 - ±i< £ •gp^e™" 2 Qh

k

. (3.101)

By using this derivation, the magnitude £ has become unstuck from its original designation as the difference between the two vectors in the Green's function. This arbitrariness can be exploited in order to accelerate the convergence of the lattice sums. By making use of the recurrence formulae (see Abramowitz & Stegun 1972) (3.102) (3.103) then we find that after p successive integrations of equation (3.101), we obtain

(p-n)\

SY(k,k0)Je+p(k£) n=l

"*?(*

P

v

(2_

p-2n+2'

5e,o

'

Je+P(QhZ) 2

jeeh

(3.104)

Ql-k

Usually, for analytic purposes, p is set to zero, while for numerical applications p is set in the range 5-7. The lattice sums are absolutely convergent, with order 0(Qflp~ ' ) for large Qh- One can also see from (3.101) that S}^e = (Sj)*, where the asterisk denotes complex conjugation. Thus, only positive order lattice sums need be considered. 3.2.4

The integral equation

and the Rayleigh

identity

Applying Green's theorem within the unit cell, in the region ft shown in Figure 3.5, we have [uA'g(r; r') - g(r; r')A'u(r')] dA! l

^(r;r'Hr')-9(r;r')^(r')

r u dc

ds'

(3.105)

Multipole methods and homogenisation

148

in

two-dimensions

r-«

a r

\ C

))

fc-J I

I

i\

J/&C

»~

Fig. 3.5 The central unit cell, showing the contour within which Green's theorem is to be applied.

where T and dC are the contours shown in Figure 3.5. Here the primes indicate that the operators act on the primed coordinates only. We already know from the definition of the Green's function (3.75) that ff

[u(r')A'g(r; r') - g(r; r')A'u(r')] dA' = u{r) .

(3.106)

In addition, the quasiperiodicity of both u (3.67) and g (3.77) guarantees that the integral around the outer boundary T is zero. Thus we have the integral equation u(

r)= [ Jec

dg *\ du /_/<> {r') 7 (r; r')u{r') - g(r; r') — dn dn'

(3.107)

In order to solve this, we expand both the potential and its radial derivative as Fourier series on the boundary of the circular inclusion:

,(r)|_ = £ «**» ,

(3.108)

£=-oo

du (r) dr

r=a

E ^

^=_

(3.109)

The spectral

problem

149

Using Graf's addition formula and noting that r > r' everywhere outside the inclusions, we expand the Green's function (3.100) in coordinates centred on the origin: oo

9(r;r')

= ~

Yn(kr)Jn(kr')ein^-^

£ TI — — OO

-

OO

~7

OO

£

( - l ) m + " ^ _ n J „ ( f c r - ) J m ( f c r ' ) e i n 0 - ^ , (3.110)

£

m= — oo n=—oo

where 6 = a r g r and (f> = argr'. (The arguments of the lattice sums have been dropped for the sake of simplicity.) The radial derivative of the Green's function can be written ^ r ' ) dr

= - \

n= — oo oo

oo

"I

Yn(kr)JUkr>)e^e-<»

£

£

(-ir+nSZ-nUkr)J'm(kr>)eine-im*

£

.

(3.111)

m = — oo n = — oo

We can now evaluate the integrals around the boundary of the inclusion. The first of these, from (3.107), is

jNMgcr^-jf

£

aeel

.l=-oo

Yn(kr)J^kr')ein^^

£

(3.112)

n = —oo ,

oo

4

oo

£

{-l)m+nSl-nUkr)J'm{kr'yne-im* ad<j>

£

m = — o o n = —oo oo

=

£

y*(fcr)e*

* ) .I »^ ( f c a ) -«< (I —^-

£=-oo

oo + £

oo £

n=—oom=—oo

r J„(fcr)e^(-ir+"^_„

- a L

m

/ / \ " ( ^ W a ) . \

/

(3.113)

150

Multipole

methods

and homogenisation

in

two-dimensions

The second integral in (3.107) is £4>

E A''

Jt=-oo 1

°°

- Y, Yn(kr)Jn(kr')ein(9-^

(3.114)

n=—oo oo oo

~ I

E

(-Vm+nS}n-Mkr)Jm(kr')eine-i

E

m=—oo

= oo

ad(j>

n=—oo

£

y,(fcr)e^[-/3,(^)j,(fca)

oo

+ E

^ ( * r ) e < n * ( - i r + n S £ _ n [-/3m ( y ) Jro(fca)' .

E

n=—oo m=—oo

(3.115) We can now write out the potential explicitly: oo

oo

n = —oo oo

+ E

(-l)m+nSm-nJn(kr)eind

E

n= — oo m=—oo

x ( Y ) [-o<mkJm(ka) + (3mJm(ka)}

(3.116)

On comparison with the original expansion of the potential (3.70), we now make the identification Bn = ( ^ ) [-OnkJ'^ka)

+ (3nJn{ka)}

(3.117)

OO

An =

£

( - l ) m + n S £ _ „ ( y ) [-a ro fcJ^(fca) +/3 m J m (fca)]

m= — oo

(3.118) Hence it immediately follows that oo

An = £

(-ir+"S£_ n £ m .

(3.119)

The spectral problem

151

This equation has become known as the Dynamic Rayleigh Identity. By using the definition (3.73) which incorporates the boundary conditions, we can write the Rayleigh Identity in the form oo

MeBe+ ] T (-l)i+mSl_e(k,k0)Bm

= 0.

(3.120)

m=—oo

This is an infinite linear system, which can be truncated and solved for the coefficients Be. Zeros in the determinant of the above system then correspond to propagating modes, and becausefcoand k are the only free parameters in the system, setting the determinant to zero will generate the dispersion relations, or photonic band structure, of the material. The structure of (3.120) is important. The quantities Me in the first term depend on the cylinder radius and refractive index, but not on the parameters of the array itself. Conversely, the lattice sums Sj depend on the geometry of the array but not on the characteristics of the cylinders. This separation is useful in analytic studies of the system. Due to the symmetry both of the cylinders and of the lattice, we also have the relations M_ £ = Me

(3.121)

SZt = Sj*

(3.122)

where the star (*) denotes complex conjugation. One can immediately see that the system (3.120) is Hermitian. The system (3.120) is readily normalised; by setting zm = y/\Mm\Bm we can re-write it in the form (7 + R(w,fco))Z = 0 ,

(3.123)

where I is the identity matrix, Z is the vector of unknown coefficients Zm and R(u>,fco)is a matrix whose components are Rem = (-lY+msgn(Me)

!^±^ . yJ\MlMm\

(3.124)

When written in this way it can be shown that the coefficients of the matrix R(u>,fco)decay exponentially away from the main diagonal. From this observation it is apparent that the coefficients Ze decay very rapidly with increasing £, and so it is not always necessary to consider a large number of terms in the calculations.

152

3.2.5

Multipole methods and homogenisation

The dipole

in

two-dimensions

approximation

For arrays of cylinders which are not too concentrated, we can neglect all terms in the system (3.120) which are of higher order than the dipole (B±i) terms. If we truncate the system (3.120) to include only terms from m = —1,0,1 and equations from (. = —1,0,1 we obtain the 3 x 3 system

Mi + Si

-S\

-SY*

Mo + SX

SY*

-sY*

sY

'

-sY

•B_r (3.125)

B0

MX + SY _

.Bi

.

Specifying a direction for ko, i.e., the value of 6Q, we can evaluate \V\ as a function of k and ko. Then, the condition \T>\ = 0 defines k as a function of ko. We are particularly interested in this function in the neighbourhood of ko = 0, since this is intimately connected with the behaviour of the system of cylinders for wavelengths A > ( i and thus with the homogenisation of the material. It has already been mentioned that the lowest frequency mode, known as the 'acoustic mode', determines the homogenisation of the material. For the acoustic mode, we will assume that k oc ko for ko —>• 0, for the reason that if we do otherwise the material cannot be homogenised at all. Hence, we will define: k = ako,

(3.126)

and assume that a has the following expansion: a = a0 + a2(k0d)2 + O{k0d)i.

(3.127)

Here, ao and a? are quantities we seek to determine: ao is related to an equivalent (phase) refractive index for the array, through the relationship (see equation (3.69)) 1

(3.128) a If one wanted to measure neg experimentally, then one could insert a sample of the composite in one arm of an interferometer, and then measure the resulting phase shift. a2 is the first estimate for the coefficient specifying the nen =

The spectral problem

153

wavelength dependence of a, and so will determine the first finite frequency correction term to the effective refractive index. We now employ the substitution (3.126), and seek to determine the small fco expansion of a from the equation \T>\ — 0, i.e.

(M0 + SX)[(M1 + SZ)2-\sZf -2 \SY\2 (M1 + Sf) + (SY)2Sr + (SV)2SZ = 0. (3.129) We have from (3.74) the following series expansions for small fc:

Mo Mi =

32 ir{n - l)(fca)4 2

l-rt-QW+Ojka)* 1 , M

7r(fca)

2

In I y J + 7 •

(3.130) n2r + 3 4(n2 - 1)

0(ka)4 (3.131)

where 7 represents the Euler constant. It should be noted that this asymptotic limit depends both on the material properties of the inclusions and on the type of wave propagating through the array. In this case we consider, as before, a Transverse Electric wave moving through an array of cylinders with refractive index nr. We also obtain from (3.101) for small k and fco: ^0

—


J

IT

1 4iexp(i#o) &o 2 k V k — k2
s\ = qy

_ 1M

*

~ d

2

— + 47o^ - - In (fed) + O(feod), (3.132)

2

k

2

IT

-£.\+0{kod), 4-7T j

(3.133)

d2\ k2-k2

AIT2

8TTJ exp (2i00)

a\ ' exp (—2i#o) + O(k0d),

(3.134)

where 70 = -0.318895593319827 and
154

Multipole methods and homogenisation

in

two-dimensions

portional to cos (40o). This is a consequence of the four-fold symmetry of the square array, i.e., the invariance of the array with respect to rotations of an angle which is an integer multiple of 7r/2. If we express the cylinder radius a in terms of the area fraction of the cylinders (/): 2\l/2

(3.135)

a =

•K

and replace n^ by: T+ l

(3.136)

with 1/r representing the dielectric contrast across the interface boundary, then in the expansion of (3.129) the leading term (of order l/A;®) is: _256TT(T-1)(T + / ) 2 8

~

ag(a§ -

l)fd*k*

«8

/ r +f

(3.137)

Hence, we obtain for ao: T-f an = T + f

(3.138)

Equation (3.128) gives us the leading order estimate for the effective phase refractive index (or dielectric constant eeff):

KV) 2 =

£

e« —

T+f T-f

(3.139)

This is, of course, the Clausius-Mossotti or Lorentz-Lorenz equation, derived earlier in section 3.1.2. Having found a 0 , we now seek to determine »2 by setting equal to zero the coefficient of 1/fcg in \V\. Thus, we find: Mi + 5 0 y =

2(r + / ) 2 _ _ (T - f)fd?k2Q "+ 7T ' " \A-K

UJl

2r-l

+

2-K

^-2-p^^2+O(k0df,

(3.140)

The spectral problem

155

and:

™ (Mi + S*)

|0y.2

# r=

l l 4(r + / ) 2 2 2 IT (r - /)/d fc

1 T+ f

-470 + r

1 T+ /

7~ -j

/ / \

n

, 2r-l

\ 4-K J (4)

7 ^2

cos

2lT

(4(?0

16a 2 (r + / ) 9 / 2 + O(fcorf)0. 3 / (T - /) 3 / 2 d 2 fc 2

(3.141)

The coefficient of 1/fcg in (3.141) vanishes by virtue of (3.138). Since we want the coefficient of l/A;® in (3.129), we need to take into account only the leading order term in MQ + S%: y 167r(T + / ) 2 ( T - l ) Mo + 50y = + c?(Mr (*

(3.142)

7)W^

The calculation of the leading-order contribution from the second and the third terms in (3.129) is simpler than the treatment of the first term. We need only take the leading term in each quantity, and replace a by ao throughout. We find:

-2 \s\|2 (Ml + s*) = (sl)2 sr + (sV) si72 y }

16(T + / )

5

(3.143)

= -(T_/)2/3rf6fc6+<W) By substituting (3.142) and (3.143) in (3.129), we have:

(3.144) Then, by equating (3.141) and (3.144) we obtain: / «2

4

a

(T-/)

(T

+

1 / a

/)5/2 ^

n

Jl

l n

m,

L

^47f

+

1 r + / 27TT-/

_ _ _ _ 4 2

T2-/2

1

2T-l 7 0

-2TT ^ T - 1

11

T (4)J 1 - - cr^ cos (40 o )

7T

(3.145)

156

Multipole methods and homogenisation

in

two-dimensions

Consequently, we obtain from the dipole Rayleigh equations, the effective refractive index of the array: (n e ff) 2 =

-470 -

7S 1

1 r1

TT 27T

f

T - 1

/;2i M

2/2(T-/)1/2 2(T + /)5/2

, 1 T+f

+ Z7T T — /,

2 T - 1

ir

\47ry

+

(^ 2 (4 ) .l--<#'cos(40o) \

2?r

(3.146)

7T

for |T| > / and r ^ 1. For complex r there is a branch-cut on the real axis, for — / < r < / and a simple pole at r = 1. The branch-cut corresponds to real and negative values of the relative dielectric constant of the cylinders sr = r?r (lying between - ( 1 — / ) / ( l + / ) and its reciprocal). Such values of er are of course not physically realisable. By means of (3.145) we may study the validity of the Lorentz-Lorenz formula for square arrays of cylinders, having different area fractions, refractive indices of cylinders or orientation angles of the Bloch momentum. In the graphs displayed in Figures 3.6-3.8, the value of area fraction has been limited to / < 0.5 as all the calculations have been made in the dipole approximation. For concentrated systems one would have to extend

o.oi

-0.01 Fig. 3.6 The first dynamic correction 0:2 as a function of area fraction ( / ) , for 9Q = ir/3. The dashed lines correspond to a square array of cylinders, having eT = 5 (short-dashed curve), eT = 10 (medium-dashed curve) and eT = 20 (long-dashed curve), while the solid curve corresponds to an array of perfectly conducting cylinders.

The spectral problem

it/4

"0

Fig. 3.7 The first dynamic correction a ] a s a function of orientation angle (60), for / = 0.4. The dashed lines correspond to a square array of cylinders, having ET = 5 (short-dashed curve), er = 10 (medium-dashed curve) and e r = 20 (long-dashed curve), while the solid curve corresponds to an array of perfectly conducting cylinders.

the matrix in (3.125) for \P\ > 1, in order to include the contribution of high-order multipoles. Thus, in Figure 3.6 one can see the dependence of ai on the area fraction (/), for a fixed orientation angle (#o = TT/3) and various relative dielectric constants (er) of the cylinders. One interesting feature of these curves is that they cross the /-axis (c*2 — 0) even for relatively high contrasts. This could explain why the Lorentz-Lorenz formula works well in such cases. Actually, this result depends on the orientation angle of ko, as can be seen in Figure 3.7. In some cases, like / = 0.4 and e r = 20, a2 is different from zero for all the values of orientation angle in the range 0 < 60 < 7r/4. We may say that 0*2 is small for / < 0.4 and er < 10, independently of the orientation angle #0 (see also Figure 3.8). A number of comments can be made about the form of (3.146). Firstly, m if we replace r by —T in the leading term, e°ff is replaced by l/e\, accordance with Keller's Theorem (Keller 1964). The dynamic correction term gives a form not obeying Keller's Theorem: this we would expect since Keller's Theorem is based on the Laplace's equation, and dynamic fields come from potentials obeying the Helmholtz equation. Secondly, we may enquire as to the values of / and r for which the static result (3.139)

158

Multipole methods and homogenisation

in

two-dimensions

Fig. 3.8 The first dynamic correction 02 as a function of relative dielectric constant of the cylinders (er), for 0o = ir/3. The different curves correspond to a square array of cylinders, having / = 0.1 (short-dashed curve), / = 0.2 (medium-dashed curve), / = 0.3 (long-dashed curve) and / = 0.4 (solid curve).

is a good approximation. The requirement is then: (k0d)2

<

4TT(T +

/)5/2

-2-/2 r-1

2 In

, r +f /

+

w

+ 2r - 1 - 8TT7O

1 - - 4 4 ) cos (40o)

(3.147)

TV

This requirement becomes less stringent as / decreases. However, as nr increases, r decreases toward one, and the term (r 2 — / 2 ) / ( T — 1) in the denominator makes the requirement stronger. Thus, if nr is sufficiently large, it may require very low frequencies before the quasistatic region indicated by the inequality (3.147) is attained. Finally, the first dynamic correction to the effective dielectric constant involves a quadrupolar dependence on direction within the array.

3.3

The singularly perturbed problem and non-commuting limits

An interesting mathematical quandry arises when we attempt to take the limit when the transport property n becomes infinite. We might proceed

The singularly perturbed problem and non-commuting

limits

159

to take the limit as follows: One reason that the potential u is unaffected by this limit in the region between the cylinders, and continues to satisfy the Helmholtz equation: (A + A;2)w = 0.

(3.148)

Meanwhile, it is apparent that the boundary conditions (3.65) and (3.66) are changed into the single Neumann condition du dr

= 0,

(3.149)

dtvo

This corresponds to the case when the cylinders are 'perfectly insulating' or 'vacuous'. On the other hand, if we write the expression for the potential inside the inclusions as (A + n2fc2) u = 0,

(3.150)

one can see that when n —> oo the term on the right hand side dominates, and hence u —> 0. In this case the boundary conditions (3.65) and (3.66) are converted into the single Dirichlet condition u\d„0

= 0.

(3.151)

This corresponds to the case when the cylinders are 'perfectly conducting' or 'rigid'. In fact the problem when n is large is of the singularly perturbed type. If we write the expression for the potential inside the inclusions as fc2n2

A + l ) u = 0,

(3.152)

then one can see that when the quantity kn is large there exists a small parameter near the higher order derivatives in the equation. Solutions to this type of problem typically involve large derivatives and possibly highly oscillating fields inside the inclusion and in its immediate neighbourhood in the matrix. As we shall see, the occurrence of such large derivatives does not preclude a satisfactory mathematical treatment of the problem. It is instructive meanwhile to continue with both our naive models (3.148), (3.149) and (3.150),(3.151), because this highlights an interesting 'paradox' which occurs when the situation is treated non-rigorously. We proceed as follows:

Multipole methods and homogenisation in two-dimensions

160

3.3.1

The Neumann

problem

and non-commuting

limits

The potential is still quasiperiodic (satisfies (3.67)), and in the material outside the cylinder has the general form (3.70). It follows that the coefficients A( and Be from (3.70) satisfy equations of the form (3.73), with: M!°

=

y/(fcq) J't{ka) •

(3.153)

Consequently, we have to change only the coefficients Me in the Rayleigh identities (3.120), while the lattice sums SY remain unchanged. This gives the dipole approximation of the Rayleigh system in the form (3.125), with the determinant:

(MST + SY)[(M? + SY)2-\SY\2] -2 |SrI* {M? + SY) + (Si)2 Sf + (SV)2SZ = 0. (3.154) Now, from (3.153) we have the following series expansions for small k: 4 7r(A;a)2 4 M1°°

=

^

+

5 + 47

JbW 2,

+

^N

(ka\

_,

2

. ,2

(3-155) (3.156)

The lattice sums Sj, of order £ = 0,1,2, have the expressions (3.132-3.134). The determinant (3.154) also depends on #o through terms proportional to cos (4#o )• Again, we employ the substitution (3.126) and assume that a has the expansion (3.127). Then, in the expansion of (3.154) the leading term is of order 1/fco, and is:

T_6

64(1-/2)(1 + /) a g ( l - a g ) / 2 d 8 * g an

1+ /

(3.157)

Hence, we obtain: o& =

1 + /'

(3.158)

The singularly perturbed problem and non-commuting

limits

161

with / — Tra2/d?. We can now see that (3.158) cannot be obtained as the limit of (3.138) for r —> 1. That is, the limits k -4 0 and n —> oo do not commute. The 'paradox' can be stated in the following way: If the refractive index n of the inclusions is fixed, then the problem formulated is a regularly perturbed boundary value problem and can be homogenised in the same way as in the previous section. The limit of large n can then be taken to obtain the 'perfectly conducting' result. On the other hand, if we allow the product nk to be large when we first start to treat the problem, and then homogenise the material, then we obtain a different answer. That is, the final result for the homogenised material depends on the order in which the two limits are taken. If we plot the limit taken on the coordinate axes 1/n and k then we might anticipate that the result for a depends on the trajectory as we approach the origin in the plane (1/n, k). In particular, when 1/n = kp, with p > 1 (the curve 3 shown in Figure 3.9) then the parameter kn in (3.152) is indeed small and we deal with the case of a singularly perturbed boundary value problem. If n is complex with a sufficiently large imaginary part, then we expect the field to attenuate as one moves away from the interface k 0.8

^ ^

0.6

0.4

0.2/

-*— n 0

S'

2

/

s^

s'

-1 , , —T"-^!^

0 1 0 2 0 3

X/N

0 4 0 5

Fig. 3.9 Trajectories in the (1/n, k) plane corresponding to a regular perturbation (1), transition region (2) and a singular perturbation (3). The three trajectories correspond to the power laws with respective exponents less than one, equal to one and greater than one.

162

Multipole methods and homogenisation

in

two-dimensions

boundary, and a thin layer (the boundary layer) would exist in the vicinity of the interface where the field is characterised by relatively large values of its gradient. If n is real and large the field oscillates rapidly inside the dielectric, and it is more difficult to characterise the boundary layer. 3.3.2

The Dirichlet

problem

and source

neutrality

Starting with the Dirichlet problem (3.150),(3.151), we note once more that the coefficients Ae and Be from (3.70) satisfy equations of the form (3.73), with:

Consequently, we have to change only the coefficients Me in the Rayleigh identity (3.120), while the lattice sums Sj remain unchanged. The central term in the Rayleigh system (3.120) is M0 + S% ,

(3.160)

and when we take the limit k —¥ 0, this becomes

I (ta+->) ~ a^W) - ( T + 4 7 ° ) - 1 l n { k d ) + ° { k d )

(3 161)

-

It is readily verified that no other term in the system can cancel out the constant term 2/n\n(a/d) appearing in (3.161), with the effect that k will not necessarily vanish as ko —¥ 0. We can see therefore that the presence of the lowest band is strongly dependent on the coefficient Mo. This coefficient is related to the flux across the cylinder boundary, through the equation

-^dl = 2nkaB0 [-M0J0(ka)

+ Y0'(ka)]

(3.162)

In the context of electromagnetism, the flux integral on the left hand side is proportional to the charge on the cylinder. This suggests that source neutrality is a pre-requisite for homogenisation of the material. In fact if we set the problem up so that it is source neutral, i.e. so that

/

du —dl = 0 ,

(3.163)

The singularly perturbed problem and non-commuting

limits

163

then the boundary coefficients become

(3-164)

Mo = ^ g 4 = °^ • J'0[ka) and M„ = ^ M = 0 ( f c 2 " ) ,

(3.165)

as k -> 0, so that the terms of order fc2 (and smaller ones) cancel the singularities in S^, S j ' , 5 ^ (all of order (fc2 — fcg)-1). This gives rise to a linear acoustic band k = ako, and it can be verified that the expression for the slope a is the same as for the Neumann problem, i.e.

a=

(3 166)

\lT^J

-

where £eff is this time the effective dielectric constant for an array of perfectly conducting cylinders. Source neutrality, amples

non-commuting

limits and some model ex-

By way of illustration, and in order to demonstrate that these effects occur even in simple materials which are non-periodic, we now present three elementary examples. Example 1 - Dirichlet problem with a constant boundary value. Consider an infinite plane, and let v(x, y) be a linear function that describes a potential of an applied electrostatic field. Introduce a perfectly conducting infinite cylinder of circular cross section (of radius a), and assume that the potential of the electrostatic field is constant on the boundary. Thus the problem can be characterised as Au(x, y) — 0 u

x2-\-yz=az

C,

(3.167) 2

2

u(x, y) — v(x, y) + w(x, y) as x + y —>• oo ,

164

Multipole methods and homogenisation

in

two-dimensions

where \Vw\ —>• 0 at infinity. The solution of (3.167) has the explicit form u(r) = v ( r ) - ( l o g a ) - 1 ( i > ( 0 , 0 ) - C ) l o g r

(1

01)

I

01) \

( cos6»—+sin6>—- J , (3.168)

where r = (x,y) = (rcos6,rsin9). Note that this representation includes a logarithmic term unless C = v(0,0). For the latter case the integral of du/dn over any closed contour (which does not intersect the inclusion) is equal to zero. Thus, an appropriate choice of the constant C provides source neutrality. Example 2 - The Neumann problem for a perfectly insulating inclusion. Now assume that the circular inclusion is perfectly insulating, and, therefore, replace the boundary condition in (3.167) by du dn

= 0

(3.169)

x2+y2=a2

The field u then admits the following explicit representation: a2 / dv u(r) = «(r) + - ^CoS9~+Sm9-j

v

n®

\

,

(3.170)

and it is straightforward to verify that this automatically satisfies the source neutrality condition. Example 3 - Oscillation in a body with a small perfectly conducting or perfectly insulating inclusion. Consider the eigenvalue problem Au + fc2w = 0 in n \ D e fill

/3u +

^ - = 0 on a n on -^ = 0 on dV£, on

(3.171)

where 0 represents a bounded region and V£ is a small disk of radius s. Let uo, ko be the eigenfunction and the eigenvalue respectively that solve the following spectral problem in £): Au 0 + kl = 0 in fi 5 ^ = 0 on dQ. on

(3.172)

Non- commuting

limits for the effective

properties

165

When (3 — 0, we deal with the homogeneous Neumann condition prescribed on dVs (perfectly insulating inclusion), whereas for (3 —• oo we have prescribed a homogeneous Dirichlet condition (perfectly conducting grounded inclusion). As fco —• 0, the function UQ is constant, say 1, to leading order, and the derivatives duo/dx(xo,yo), duo/dy(xo,yo) are of order O(fco); here (xo, yo) are the coordinates that correspond to the center of the small inclusion. The asymptotic problem (3.171) is classified as a singularly perturbed problem, and it requires a boundary layer which describes the field in a neighbourhood of the inclusion (and depends on scaled coordinates). This problem was studied by Ward and Keller (1993), who derived the following asymptotic formulae for the eigenvalues: fc2 «fcg-(loge) _1 27r[uo(a:o,J/o)] 2 , when j3 -)• oo,

(3.173)

and

fc2«fc02jl+£2

•K\uo{xo,yo)\

-2ir-

k0

when (3 = 0. (3.174)

We note that for the case of the perfectly conducting grounded inclusion the source neutrality condition is not satisfied, and even if fc2 —• 0 the eigenvalue fc2 does not necessarily vanish for any fixed e. When, however, the inclusion is perfectly insulating, the quantities fcg and A;2 have the same order of magnitude (for a small fco we can guarantee that ke will also be small).

3.4

Non-commuting limits for the effective properties

Consider a periodic structure such that each cell contains a highly conducting inclusion. The region occupied by the inclusion is denoted by fi^; the remaining part of the unit cell is designated as Jl( m ). We also consider two problems for the fields V and V, each satisfying the continuity condition (3.65) and the interface condition for the normal derivatives dV(i) dV(m) C ^ T (*>*)= *T 0^)'

(*,3/)€3fi(i),

(3-175)

166

Multipole methods and homogenisation

in

two-dimensions

where £ = 1 for the case of TM polarization and ( = 1/N2 for the case of TE polarization. V satisfies the Helmholtz equations (3.63) and (3.64), while V satisfies corresponding equations, with k replaced by k. The quasiperiodicity conditions are ,

(3.176)

exp(-ik0d)V(x,y)

(3.177)

V(x + d,y) = exp(ik0d)V(x,y) V(x + d,y) =

In what follows, we assume that an acoustic band exists, i.e. (3.178)

lim fc/fco < M , feo->0

where M is constant. The following identity then holds:

JJu(m)

+c =

y( m )AV( m ) - y( m )AV( m ) dA

11

y-WAyW - y W A V ^ dA

(k2-k2) N2(

IJ

V^V^dA

m

+ J Jn (m) V(

)v(m)dA (3.179)

On the other hand, it follows from Green's theorem that y(m) ^

y(m) dn

I +C

y(m)

y-(m) dr

L

dl

dn

y(i) — dr

dl

dr

vw

dr

(3.180)

dl

where 7 denotes the exterior boundary of the unit cell, and Y — dil^y Due to the continuity conditions (3.65) and (3.175), the last two integrals in (3.180) cancel and the quantity I in (3.180) involves only the line integral over the boundary 7 of the unit cell. Only the lines x = ±d/2 of 7

Non-commuting limits for the effective properties

167

contribute to the line integral I and it follows from the quasiperiodicity of V and V ((3.176) and (3.177)) that y W _

j l - exp [-i(k0 - k0)d] \ I

y("») dn

v

dn

dl. (3.181)

where 7^ = {(x,y) : x = d/2, -d/2 < y < d/2}. When k0 ->• 0 the fields V and V in both the matrix and the inclusion may be represented in the form: W i,m > = exp [iJfcou,i>m>] + 0{kl) , {i m

V ' ^ = exp [-ikou^] where Us satisfies:

+ O(fcg) ,

(3.182) (3.183)

is a static field. The field us is a harmonic function which u
du dn

=u®{x,y),

6V(*) = C" dn

on the interface a;2 + y2 = a 2 , and may be written in the form us = x + Us , where Us is a doubly periodic function. The TM case (C = 1) corresponds to an ideal contact (a homogeneous plane without any inclusions at all), while the TE case (£ = 1/N2) describes an array of circular dielectric cylinders of 1/iV2 dielectric constant embedded in a matrix of unit dielectric constant. Using (3.182) and (3.183), equation (3.181) reduces to: ,{m)

/7r .~2

(ko

i{k0 + * o ) - ^ - exp [t(*o - fco)«.m) + 0(*g)J