Advances in Applied Mechanics, Volume 30

+

nl 1 814 E‘ 1 + 8 / 3

(2.15)

In the problems of crack interactions, considered in this work, the nonuniform tractions represent additional tractions on cracks due to interactions. In such problems, the coefficient /?(of the polynomial (2.14)providing the best fit for the actual tractions) may reach values on the order of unity (for extremely strong integrations) but is, usually, substantially smaller than unity. Then the ratio (1 + /?/4)/(1 + 813) in (2.15) is close to unity. (For example, in the problem of two collinear cracks with spacing between cracks of 0.2 of the crack length, B = 0.22. Then this ratio is 0.983.)In conjunction with a similar fact for the mode 11, this means that the proportionality (2.13) can be viewed as a sujiciently accurate approximation. (Note that, if the cubic polynomial (2.14)is upgraded to the seventh degree, with coefficients 6 and o at the fourth and sixth powers, then 618 + 501128 and 615 + 017 should be added to the numerator and denominator of the mentioned ratio; since the coefficients at increasing powers of the (2.14)-type polynomial, typically, rapidly decrease, such an upgrading is not expected to have a strong impact on the proportionality relation (2.19.)

B. THREE-DIMENSIONAL FIELDS(CIRCULAR CRACKS) 1. Stresses Generated by a Crack Loaded by Uniform nactions (Normal

and Shear)

Expressions in terms of integrals of Bessel functions can be found in the book by Sneddon and Lowengrub (1969). More useful expressions in elementary functions (2.16) and (2.17) are due to Fabrikant (1990). Cylindrical coordinates p = (x2 + Y ) ” ~ , 4 and z are used; crack radius is a and

Mark Kachanou

272

r = (x2 + y2 + z ' ) ~ ~Note ~ . that in the axisymmetrical problem of uniform normal loading, the dependence on c$ will disappear if stress components in the cylindrical (rather than Cartesian) coordinate system are used. Formulas (2.7),(2.8),(2.12), and (2.13) assume that z > 0; stresses in the lower half-space z < 0 are found from the symmetry relation oi,(x,y, -z) = aij(-x, -y,z). a. Uniform Normal Loading p

q 1+

61

= It

62

=-

a(13 - a2)1/2

1; - 1:

2 4

2p al:e2'+(1: - a' 71 l;(l; - 1;)

'

lj2

- arc sin

{I - 2 v +

(31

zZ[a2(61: - 21:

(1:

- l:)'(l;

+ p 2 ) - 51:] - a2)

(2.16) where the following notations are used: 61

= ox,

c2 = ox,

+ by, - oYy+ 2io,,

6, = 6 2 2

z, = ox,

I, 12

+

idyz

+ + Z 2 - y - [(a - + z2]1'2} = 1/2{[(a + p)Z + z2-y + [(a + z2]1/2} = 1/2{[(a

p)2

p)2

p)2

b. Uniform Shear Loading z (arbitrarily oriented to the x, y axes: iz,)

t = z,

01

=

+

{

2(iei4 + t e - '4 -2(1 4 2 - v)

+ v) a11(a2 lz
l y 2

Elastic Solids with Many Cracks and Related Problems 02=

2ei+

-~

742 - v)

- v,

al,(a2 - /;)'I2 12(1; - 1;)

z/,(l; - a2)1/2

+

12(1i- 1:)

+

a2(41; - 5p2) + 1; (z (1; - 1:)z = -

+ ?e2'+)

+

2(?ei+ re-'+) zll(l; - ~ ~ ) ' / ~ [ a ~-( 5p2) 4 1 ; + l;] n(2 - v ) i2(i; - 1 3 3

Z(U'

273

(2.17)

+ a2(2a2+ 2z2 - 3p2)]

- l;)'"[l;

(1; - 1 3 3 112

+

z(a2 - l:)'I2[a2(61: - 21:

(1; - 1:)2

+ p 2 ) - 51:]

2. Stress Intensity Factors

SIFs are, generally, variable along the crack edge. Mode I is decoupled from modes I1 and 111, but modes I1 and 111are not decoupled shear loading produces a combination of modes I1 and I11 conditions along the crack edge. A pair of equal and opposite point forces P (normal to the crack) applied to opposite crack faces at the point po, 4oproduces the following mode I SIF at a given point 4 of the crack edge:

Kd4) =

1 ~

n2J2aa2

P

+ P?l - 2apocos(4 - 40)

(2.18)

Modes I1 and I11 SIFs at a given point 4 of the crack edge due to a pair of arbitrarily directed shear forces T = T, + iTy applied to opposite crack faces at the point po, 4o were recently obtained by Fabrikant (1990) in the following convenient complex form (the overbar denotes a complex conjugate):

274

Mark Kachanov

For a uniform normal load p K , = p(2a)’”a-

(2.20)

Uniform shear load 7 produces the following values of K,,and K,,, along the crack edge:

3. Variation of the Energy Release Rate along the Crack Edge under a Uniform Shear Loading

The energy release rate along the crack edge is

(2.22) where the first term in the brackets represents the average along the edge value, and the second term represents the variation; the ratio of G ,, (at the point of pure mode I1 condition) to Gmin(at the point of pure mode I11 condition) is (1 - v)-’. In a very rough first approximation, the second term in the brackets can be neglected (particularly if v is small) and G can be taken as constant around the edge. It should be noted, however, that G, as written, is relevant for the in-plane crack extension only. Actually, as the propagation condition is first met at the point of pure mode 11, the crack will kink at this point, and according to the results for a (locally 2-D plane strain) kinked crack (Cotterell and Rice, 1980), pure mode I conditions exist at the kink tip and K , = 2 / f i K , , . On account of this factor, the G at the point of kinking exceeds the one at the point of pure mode I11 condition by the factor of (4/3)(1 - v)-’, a noticeable difference. 4. COD of a Circular Crack Loaded by a Uniform Paction

COD due to a uniform normal loading p is given by the expression (2.23) In the case of a uniform shear loading, the COD vector is collinear to the direction of loading (note that this would not be true for an elliptical crack, see Section VI) and its magnitude is obtained from (2.23) by dividing it over (1 - v/2).

Elastic Solids with Many Cracks and Related Problems

275

Thus, in contrast with the 2-D case, “compliances” of a crack in the normal and shear directions are different (although not by much). Therefore, in the case of a uniform traction arbitrarily inclined to the crack, the vector of COD is not collinear to the traction vector. Implications of this noncollinearity for the effective elastic properties of a cracked solid are discussed in Section VI. Average normal and shear CODs produced by uniform normal, p , and shear, z, loadings are

C. FAR-FIELD ASYMPTOTICS At distances from the crack that are much larger than the crack size the expressions for stresses simplify. They are given by the following formulas (uniform loading p , 5 and s in modes I, I1 and 111, respectively, is assumed). 1. 2 - 0 Case

Here, l/(x2 + yZ)l/’ is a small parameter. a. Mode I Loading Oxx

+

12x4- 6x2y2 y4 2 (x2 y 2 ) 3

=P-

+

byy=

f2 x4 + 6x2y2 - 3y4 P2 (x2 - y2)3

OXY=

P l2

(2.25)

(x2 - 3y2)xy (x2 - y2)3

b. Mode I1 Loading Oxx =

(3x2 - y2)xy -d2

(x2

dyy=

r12

OXY=

‘y

+

y2)3

(2- 3yZ)xy (x2

+ y2)3

l2 x4 - 6x2y2 + y4 (xZ

+ y2)3

(2.26)

Mark Kachanov

276 c. Mode Ill Loading

3 x2 - y 2 2 (x2 y2)2

XY

oxy= - s12 (x2

oyz= s - l 2

+ y2)2’

+

(2.27)

2. 3 - 0 Case Here, crack radius is a; a/(p2

+ z2)lI2 is a small parameter.

a. Normal Loading p4

+ 8z2p2- 8z4 (p2 + Z2)Z

X

(1

+ 2v + 3(1 - 2v)cos24)p4 - 2(5 + v + 3(2 + v)cos24)z2p2+ 4(1 - v)z4 (p2 + z2)2

=’(

byy

X

)

a

3a

3

Jm

(1 + 2v - 3(1 - 2v)cos24)p4 - 2(5 + v - 3(2 (p2

(1 - 2

+

+ v)cos24)z2p2+ 4(1 - v)z4

z2)2

~ - 2(2 ) +~v)z2p2 ~ (p2

+ z2)2

(2.28)

b. Shear Loading Here, z = ( T ~zy), , and angle 4 is counted counterclockwise from the x-axis. d,,

=-

+

4(Txcos4 rY sin 4) a(2 - v)

a

4pz3 - zp3

Elastic Solids with Many Cracks and Related Problems

-

1 Jm >’ [

5zp3

zxcos 4

( p 2 + z2)2

ffYY

277

=-( 742

2 - v)

+ 4v)zp3 t, cos (b

4(1 - v)pz3 - (1

a

( p 2 + ,2)2

5zp3 - (p2

aXy = -

+ z2)2

r,sinb]

4(1 - v)(t,sin+

+ z,cos(b)

n(2 - v ) 2

a

(2.29)

- (11 - v)p2z2 3(p2

+

vp4

(p2

+

1

22)2

a

(2 - v)p4 - (1 1 - v)p2z2 3(p2

vp4

+ 2(1 +

v)z4

7,

z2)2

+ (v - 5)p2z2 ( t xcos 24 + zy sin 24)

2

+

+

+ z2)2

+ 2( 1 +

v)z4

TY

+ ( v - 5)pZzZ (t,sin 24 - zycos 24)

(p2

+

1

22)2

3. Applicability of the Far-Field Asymptotics

The expressions for the far-field stresses are simpler than the corresponding exact expressions. The question arises, at which distances from a crack do these asymptotic fields provide a sufficiently accurate approximation? Fig. 6, (a) for 2-D and (b) for 3-D, shows the regions where the errors of approximation of the actual fields by their far-field asymptotics are within 20%, 5% and 2% (for all stress components). We note that the far-field asymptotics become applicable at relatively close distances from a crack, particularly in the 3-D case and particularly in the coplanar direction. 4. Comment on Sensitivity of the Far-Field to “Details” of Loading on the

Crack

It is interesting to note that the far-field stresses depend on the exact character of loading on the crack; i.e., substitution of the loading distribution by a statically equivalent one changes the asymptotic far field. The far fields given previously assume uniform loading, and have to be changed if the loading is changed to a statically equivalent one. In the 2-D case, such an

2 0 . MODE I

Z-D, MODE 111

n 1

-

2-

2%

5%

3 - 20%

3 0 . SHEAR MODE (CROSSSECIION NORMAL TU DIRECTION OF S m )

3-D.MODE I

Q:

3-D, %EAR MODE (CROSSSECIION PARALLU TU DIRECnON OF S E A R )

1

-

23-

2% 5% 20%

(b)

FIG. 6. Regions where the far-field asymptotics of the crack-generated stress fields are applicable with the accuracy marked: (a) 2-Dcrack; (b) 3-D (penny-shaped)crack.

278

Elastic Solids with Many Cracks and Related Problems

279

adjustment of the far field is simple; it is based on the fact that for a (statically equivalent) pair of point forces applied at the point x = a of the crack ( - I , I), the far-field stresses given by (2.25) to (2.27) have to be multiplied by (4/lr)[l - (a/1)2]'/2(in all modes). For example, for point forces applied at the median point of the crack the far-field stresses are 4/lr times higher than the ones generated by a (statically equivalent) uniform loading. In this sense, Saint-Venant's principle does not hold for a solid with a loaded crack.

D. CRACK TIPFIELDS Counting the x-coordinate from the crack tip, and denoting 8 = arctan y / x , we have the following asymptotic stress field near the tip. They are shown

in Fig. 7.

a. Mode 1 Field 6

,

$Frcos (:)[I-

ayy

=

5

oxy=

,

=

-sin(')sin(:)]

~

[1 + sin (') sin J2xrcos("> 2

5 J2.r cos

(i)

sin

(31

(3 (y) sin

FIG.7. Angular variation of the asymptotic crack tip fields.

(2.30)

280

Mark Kachanov

b. Mode I1 Field u,, =

cyy=

3 sin @

3

(i)[z + (i) cos

5

uXy= @"OS

cos

I):(

1

sin(;)sin(;)]

(:) (:) ('5)[ -

[sin

cos

(31 (2.31)

sin

c. Mode 111 Field

- KIII

ax== -sin

JG

(i),

uyz=

-

&,OS K1l'

(0

(2.32)

-

d. Zone of Validity of the Asymptotic Crack Tip Fields For a crack offinite size, comparison of the asymptotic crack tip field with the full stress field (generated by the crack loaded by a uniform load) shows that the size of the zone where the asymptotic field approximates the full field (for all stress components and in all modes) is quite small it constitutes 0.01, 0.02 and 0.04 of the crack length, for the accuracies of approximation of 2%, 5% or 20%, respectively. This zone is centered at the crack tip and has an approximately rhombic shape.

111. Problems of Many Cracks in a Linear Elastic Solid

A. GENERAL CONSIDERATIONS We consider an infinite linear elastic solid with N traction-free cracks (having unit normals ni) and stresses ' a prescribed at infinity. This problem can be replaced by an equivalent one: crack faces are loaded by tractions d - a ' and stresses vanish at infinity. (In the following, upper indices indicate crack numbers, and summation over them is not assumed, unless explicitly mentioned.) We further represent this problem as a superposition of N subproblems, each containing one crack but loaded by unknown tractions; the latter consist a and the unknown additional tractions due of the a'-induced tractions ni '

Elastic Solids with Many Cracks and Related Problems

t

28 1

1 k

FIG.8. Stress sul position:reduction of the problem with N cracks to N subproblems with one crack each, but loaded by unknown tractions.

to crack interactions (Fig. 8) so that, being superimposed, stress fields of all subproblems yield the prescribed tractions n i . go on crack faces. Thus, traction on the ith crack, in the ith subproblem, is j+i

<'

where is a current point on the ith crack and Atji is the traction generated (in thejth subproblem, along the site of the ith crack) by thejth crack loaded by traction tj(('). The additional tractions Atji reflect the interaction effect and constitute the unknowns of the interaction problem. Superpositions of the type of (3.1) (usually combined, in the 2-D case, with polynomial expansions of tractions and finding the polynomials' coefficients from a large system of linear algebraic equations) have been used in literature starting since the early 1970s, see Datsyshin and Savruk (1973), Gross (1982), Chudnovsky and Kachanov (1983), Chen (1984). Horii and Nemat-Nasser (1985) called them the method of pseudotractions. In the displacements formulation, similar superpositions were used by Collins (1963). We note that such superpositions also hold for finite solids. In this case, oi*uo should be replaced by the tractions induced along the ith crack site (in a continuous material) by loads at the boundary; they may be variable along the ith crack. Finding these tractions requires solution of the elasticity problem for the finite body without cracks. Several simple configurations involving either a small number of cracks (two or three) or periodic arrangements have been analyzed in literature. In 2D, the analysis is usually done by complex variable methods, and solutions are produced either in closed form (two, or a periodic row, of collinear cracks) or numerically, usually by some sort of polynomial expansions (that,

282

Mark Kachanov

typically, become inapplicable at small spacings between cracks). In 3-D, most of the available solutions were obtained under the assumption (explicit or implicit) that spacings between cracks are not too small and the interactions remain therefore relatively weak (see Kachanov and Laures, 1989 for a review); for closely spaced strongly interacting cracks the available solutions include the work of Fabrikant (1990) on two coplanar circular cracks and solutions that can be produced by the method presented in Section B (Kachanov and Laures, 1989). Surveys of the available solutions can be found in handbooks on stress intensity factors (Tada, Paris, and Irwin, 1973; Rooke and Cartwright, 1976). Several approaches have been developed for arbitrary arrays of cracks. Since computational methods do not constitute the emphasis of our work, we mention them only briefly, referring, for example, to books by Aliabadi and Rooke (1991) and Anderson (1991) for a more detailed presentation. (1) Additional tractions Atj‘ on the ith crack can be represented as a sum Atji(ti)

= AtjU)((i) + AtW(ti)

(3.2)

where Atii(’) is the traction generated by the jth crack loaded by the noinduced traction d.uo.The second (unknown) term Atji’ accounts for the fact that the actual traction on the jth crack includes “feedback” from the other cracks. Neglect of the second term Atji’ constitutes an approximation discussed in Section C (the approximation of small transmission factors). In the next approximation, the feedback traction At”‘ can be taken as generated by thejth crack loaded by tractions that have been found in the previous approximation. Subsequent approximations are constructed as a sequence of feedback corrections. Calculation of the feedback stress fields requires integrations along the crack lines (surfaces,in 3-D) of the point force solutions (stress fields generated by pairs of equal and opposite point forces applied at arbitrary points of the cracks). The technique represents an application of the classic Schwarz-Neumann alternating method; it was applied to crack problems by several authors (Hoagland and Embury, 1980; a series of papers by Atluri and coworkers, see, for example, O’Donoghue, Nisoshika, and Alturi, 1985). It can also be applied to finite solids, by including feedbacks from the boundaries. This method may become quite intensive computationally, particularly in 3-D configurations and particularly when the number of cracks is substantial and spacings between them are small. Taking the far-field asymptotics for Atji(ti) constitutes another approxi-

Elastic Solids with Many Cracks and Related Problems

283

mation discussed in Section C (the approximation of widely spaced cracks). (2) Reduction of the interaction problem to a system of integral equations, either for the CODs (dislocation density distributions) or for the additional tractions Atji(ti)on cracks. One technique for solving such a system is based on expansion of the solution in powers of a small parameter (crack size)/(spacings between cracks); see, for example, Collins (1963) for applications to the 3-D problems. Solutions obtained this way are reliable only when spacings between cracks are not too small. As discussed in Section C, the first term of such expansions (first-order corrections for crack interactions) can actually be obtained by elementary means, with almost no calculations involved, for arbitrary 2-D and 3-D crack arrangements. A technique that has a wider applicability is to expand tractions on cracks in polynomials and reduce the system of integral equations to a system of linear algebraic equations for the polynomial coefficients. This technique is discussed in Section B.6. (3) Other methods include the finite element method with singular elements, the boundary collocation and the boundary integral methods, the weight functions method and various of their modifications and combinations. Our work focusses on physical effects produced by interactions. These effects are analyzed using the method presented in Section B. In the 3-D configurations the method is very accurate; in the 2-D configurations, accuracy is, generally, worse, but remains good at spacings between cracks substantially smaller than the crack sizes. B. A METHOD OF ANALYSIS OF CRACKINTERACTIONS

We present here the method of analysis of problems of many cracks developed by Kachanov (1985,1987).We first illustrate the method on a test problem with a known exact solution and then formulate it for the general case of an arbitrary crack array. 1. Test Problem: 7ivo Collinear Cracks The 2-D problem of two collinear cracks of equal length in an infinite plate loaded by uniform normal traction p o at the crack faces (Fig. 9) has an exact analytical solution (Willmore, 1949) and can therefore, serve as a test for our approximate method. Representing the problem as a superposition of two subproblems, each

284

Mark Kachanov

-lm-KK x m = l

FIG.9. Superposition for two collinear cracks.

containing one crack loaded by unknown tractions, we have, for the traction on crack 1, p'(x) = po

+ Apz'(x)

(3.3)

where ApZ1(x)denotes the stress oYyinduced along the site of crack 1 (in a continuous material) by crack 2, loaded by p o + Ap"(x) in subproblem 2. Tractions ApZ1(x),Ap"(x) due to interactions are the unknowns of the problem (interrelating them through integral equations would constitute a conventional approach to the interaction problem). We represent p'(x) as a sum of its average ( p ' ) = po + (Ap") and the traction nonuniformity Ap" - (ApZ1) having zero average (Fig. 10). The key simplifying assumption of the method is to neglect the impact on crack 2 of the traction nonuniformity on crack 1. Thus, the traction induced on crack 2 by crack 1 is generated by a uniform average traction (p') on crack 1 (unknown as yet). This results in a major simplification of the problem. Indeed, the traction on crack 2 is then (3.4) where the expression in brackets is the oyycomponent of the "standard stress field" (generated by a crack loaded by a uniform normal traction of unit intensity, see Section 11) induced along the site of crack 2 in a continuous material by crack 1. Thus, the average traction (p) constitutes the only

FIG.10. Traction on a crack as a sum of its average and a nonuniformityhaving zero average.

Elastic Solids with Many Cracks and Related Problems

unknown

(P')

=

of

the

problem

(by

symmetry

of

the

285

configuration,

(P2> = (P)).

We introduce a transmission factor A defined as follows. Applying a uniform traction of unit intensity to the faces of crack 1 we take the average traction cYyinduced along the site (k, 1) of crack 2 in a continuous material

The A-factor characterizes attenuation of the average traction in transmission of stress from crack 1 onto crack 2 line; A changes from - 1 to 0 when k changes from 0 to 1. Due to the symmetry of the considered configuration, A is the same in transmissions from crack 1 onto the crack 2 line and vice versa. Finding the transmission factor reduces to calculation of a line integral of an elementary function. Now (p) is readily found in terms of A: taking the average of (3.4)

fi

= P o together with ( p ' )

= (p2)

= (p), (P)

+ A(P')

yields PO

(3.6)

=-

1-A

Equation (3.6) shows an increase of the average traction due to the interaction effect. Using the general formula for SIFs at the tips of a crack loaded by a given traction distribution

and taking this traction distribution from (3.4), one obtains the following expressions for the SIFs at the outer and inner tips, respectively,

I

1 2 8 - k(k ~ ~ (=1K) ; 1 + -~ 1 - A x ( l -k)

1

1-An(1-k)

-28

n + 1 ) X - -(1 2

- k)

n + k(k + 1)X - -(1 2

- k)

where KP = p o J m is the SIF for an isolated crack and X , CW are complete elliptic integrals of the argument k = of the first and second kind, respectively. This completes the solution.

,/-

286

Mark Kachanov TABLE I ITERACTIONOF Two COLLINFAR CRACKS: COMPARISON WITH rn EXACTResu~Ts Kdk)/KP

k

K,(k)/KP

Exact

(inner tip)

Error (%)

Exact

(outer tip)

Error (%)

1.112 1.255 1.473 1.905 2.372

1.112 1.251 1.452 1.809 2.134

0.3 1.4 5.0 10

1.052 1.086 1.120 1.159 1.184

1.052 1.086 1.118 1.154 1.175

0.2 0.4 0.8

~~

0.2 0.1 0.05 0.02 0.01

These results are compared with the exact ones in Table I. The agreement is quite good. The error becomes noticeable for closely spaced cracks but even at k = 0.05 (distance between the cracks is one order of magnitude smaller than the crack length), the error is only 1.4% for K,(k) and 0.2% for Kl(l). A slight underestimation of KI is due to the neglected influence of the traction nonuniformity p f f-
(3.9)

Elastic Solids with Many Cracks and Related Problems

287

where 4, 4 are the “standard” stress fields discussed in Section I1 (fields generated by the jth crack loaded by uniform tractions, normal and shear, of unit intensity) and I is a 2-D unit tensor. The problem is thus reduced to finding the average tractions (t’) on cracks. They are found by averaging (3.9) along the ith crack line: (pi) = pi(”

+ 1 [A”.($) + A ~ ~ ( z j ) ] j#i

(3.10)

where the transmission A-factors characterize attenuation of the average normal and shear tractions in transmission of stresses from one crack onto the other crack sites; for example, A: is the average shear traction induced at the site of crack 1 in a continuous material by the normal uniform unit load o n crack 3. Note that, generally, AiJ # Aji (for example, the impact of a small crack on a larger one is smaller than vice versa). Equations (3.10) constitute a system of 2N linear algebraic equations for the average tractions. They can be written in a compact vectorial form:

-

(2dikI - Aik) (ti)

= t‘(O)

(3.11)

where summation over all crack numbers i = 1,2,..., N is assumed. Tensorial element Aikrepresents the average traction vector generated along the kth crack line by the ith crack loaded by a uniform traction of arbitrary direction and unit intensity (Fig. 11); i.e., it transforms the vector of average traction on the “source” crack into the average traction vector on the “recipient” crack line. Diagonal element Aii (characterizing “interaction of a crack with itself‘) is defined as a unit tensor I (consistentlywith the fact that tractions induced by the ith crack on lines close to I’ are close to the ones applied on the crack). The righthand part of (3.1 1) represents the remote loading conditions. The lefthand part characterizes the intrinsic geometry of the crack array, which is

FIG.11. Tensorial transmission factor.

288

Mark Kachanov

characterized, in the framework of our method, by the crack interaction matrix [A"]. Solution of the system (3.1 1) has the form (ti)

= nji.@ O .

,+ = nii,+:

(3.12)

where summation over all crack numbers j = 1,2,. . . , N is assumed, and where it is denoted (3.13)

After the average tractions (ti) are determined from this system, the actual (variable) tractions pi(t), ~'( on 0cracks are found from (3.9). The SIFs at the crack tips are then readily obtained as generated by these tractions, from (3.7). Mode I11 loading can be analyzed along the same lines. Since it does not interact with modes I and 11, the mode 111 analysis is simpler and can be done separately.In the present work, 2-D mode 111 interactions are not considered (see Huang, 1990).

3. Construction of a Full Stress Field

The obtained values of SIFs and the average tractions ( t i ) can be used to construct, in elementary functions, an approximate but quite accurate expression for afull stressjield in a 2-D solid with an arbitrary arrangement of interacting cracks. The displacement field generated by a single crack can be represented as an integral of the double layer potential type (also known as a representation of a crack by dislocations): (3.14)

where b(t) is the displacement discontinuity (crack opening displacement, COD); it is vectorial since both modes I and I1 may be present; and @ is the second Green's tensor of elasticity for an infinite plane 4nR

(1 - 2vXnR - Rn

RR1

- n-RI) - 2n-R-RZ

(3.15)

where R = 5 - x and plane stress is assumed (in the case of plane strain, the factor 1 + v is to be changed to (1 - v)-'). Differentiation of u(x) (can be applied to @ under the integral) and multiplication by the appropriate elastic

Elastic Solids with Many Cracks and Related Problems

289

constants yield the stress field a(x) if b({) is known. In the case of N cracks, we have a sum of integrals (3.14) taken over all I’ so that the problem would have been solved if the CODs were known. We suggest constructing each of the normal b, (tangential b,) components of the COD of a given crack - 1 < 5 < 1 as an ellipse that would correspond to a certain uniform normal (shear) loading multiplied by a quadratic polynomial (“polynomially distorted” ellipse): b , = -E 41 u,

(

l + a 1 , , ~1’ + / ? ~ ) / ~

(3.16)

(E‘ is Young’s modulus E for plane stress and E/(1 - v)’ for plane strain), where the three coefficients of the quadratic polynomials in each of the modes (u,, a,, /?, and u,, a,, /?,) are chosen in such a way as to match the previously found values of the SIFs and average tractions (K,( k I), (p) and Kll(f I), (T)); i.e.,

(3.17)

(Identical formulas hold for the mode I1 quantities.) Substitution of the thus found CODs b(t) into a sum of integral representations (3.14) results in a stress field expressed in elementary functions. Note that the idea of a “polynomially distorted” ellipse can be related to the polynomial conservation theorem stating that a crack loaded by a traction polynomial of degree N assumes the shape of an ellipse times a certain “distortion” polynomial of the same degree N. The shape (3.16) corresponds, therefore, to an approximation of the tractions induced on a given crack line by other cracks by a certain quadratic polynomial; namely,

(3.18)

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Mark Kachanov

with a, /3 given by (3.17). These tractions match the previously found values of the stress intensity factors and average traction on the given crack. If the polynomial approximation were based on the exact values of SIFs and the traction averages then the difference between the constructed and the actual stress fields would have amounted to a stress field generated by such a system of tractions on the cracks that (1) all the SIFs were equal to zero, and (2) traction averages on each of the crack faces were equal to zero. Such a stress field can be expected to be just a small perturbation of the actual field except, possibly, in the close vicinity of the crack faces (where the boundary conditions are not exactly satisfied). If the values of SIFs and traction averages used in (3.17) are sufficiently close to the actual ones, then the relative error in the stress field can be expected to be small. As an example, consider, again, the problem of two collinear cracks (Fig. 9) for which the exact shape of the COD is given by Sneddon and Lowengrub (1969) for k = 0.1. Figure 12 compares this shape (solid line) with the “quadratically distorted” ellipse, the distorsion polynomial being given by (3.16) and (3.17). These two shapes are very close. This indicates that the “quadratically distorted” ellipse (chosen to match the SIFs and the average tractions) is a reasonable approximation of the actual COD. Applying such representations to a solid with many interacting cracks, one obtains a reasonable approximation of the fields u(x) and a(x).

FIG.12. COD in the problem of two collinear cracks (solid line, actual shape of the cracks; dashed line, “quadratically distorted“ ellipse).

Elastic Solids with Many Cracks and Related Problems

29 1

4. Arbitrary 3 - 0 Array of Circular Cracks in an Injinite Solid The basic idea of the method remains unchanged. The “standard” stress fields are given by much lengthier expressions (2.16) and (2.17) and the directions of shear tractions on cracks have to be further specified in crack planes (it can be done by decomposing the shear tractions into the components along the 0’- induced shear tractions, r, and the normal to it, s, directions). Thus, tractions on the ith crack are:

(3.19)

where p and 4 are the cylindrical coordinates in the ith crack plane (angle 4 is counted from the direction of ricO)); “standard” stress fields @ and 4 correspond to uniform unit tractions applied in two in-plane directions, r and s (note that G; and 0; differ by 90” rotation only); r‘ and mi are unit vectors of the corresponding directions. Taking the average of (3.19) over the ith crack surface yields 3N scalar linear algebraic equations for the traction averages (ti) = ((p‘), (r‘), (si)):

(si) =

j+i

(At*(@)

+ A{;(T~) + Ait(S‘))

wnere the scalar transmission factor A$ characterizes transformation of a vector of a uniform u-traction applied at the faces of the jth (“source”) crack into the resulting average fl-traction induced at the site of the ith (“recipient”) crack and the values 1, 2, 3 of the indices a, fi indicate the normal (n) and two shear components (T and s). Note that finding the transmission factors reduces to calculation of surface integrals of elementary functions. After (ti) are determined from (3.20), the actual (variable) tractions ti(M) on cracks are found from (3.19). The mode I SIF at the given point 4 of the

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Mark Kachanov

edge of a crack of radius a due to an arbitrary distribution of the normal traction p(po, $o) is given by integration of the formula (2.18)for a point force:

The modes I1 and I11 SIFs due to an arbitrary distribution of the shear traction T (arbitrarily inclined to the x, y axes: z = zX + iz, at each point po, $o) are obtained by integration of the formula (2.19):

where an overbar denotes a complex conjugate. Thus, finding SIFs along the crack edges is reduced to 0

0

calculation of the "crack interaction matrix" [A"] (i.e., averaging of the standard fields generated by ith crack along the kth crack surface) and finding the traction averages from 3N linear algebraic equations (3.20); finding tractions tj(M) on the jth crack surface from (3.19); finding SIFs along the crack edges from (3.21) and (3.22).

The actual computational simplicity of the method depends on how simple the expressions for the standard fields are. The results of Fabrikant (1990) who derived these fields in elementary functions (see Section 11) are, therefore, essential. The numerical accuracy of the method also crucially depends on accuracy of evaluation of the singular integrals (3.21)and (3.22)for SIFs. We eliminate the singularities using the transformation suggested by Laures (1988, 1990) as follows (without it, the integration may yield errors of up to lo%, substantially exceeding accuracy of the method itself). In the integral (3.21) for the mode I SIF, we first transform the integral by changing variables (po,do)in the crack plane to variables (A, 5 ) that characterize position of the point where the load p is applied with respect to the point $ of the crack edge where K, is calculated (as illustrated in Fig. 13):

Elastic Solids with Many Cracks and Related Problems

293

X

Fic. 13. Coordinate system for calculation of SIFs along the edge of a circular crack.

Changing variables again, u = [l

+ (21-'cos5

- 1)1'2]-1

we transform the integral for K, to the form

which is nonsingular and presents no difficulty in numerical integration. In the integral for the modes I 1 and 111 SIFs, following the same steps, we transform (3.22) to the form

(3.24)

which is nonsingular. Several sample 3-D configurations of interacting cracks were considered by Kachanov and Laures (1989).

5. Accuracy of the Method As spacings between cracks become smaller, SIFs on a given crack are increasingly influenced by the traction nonuniformities on other cracks, and the presented method becomes less accurate at smaller spacings. We discuss

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Mark Kachanov

here the accuracy of the presented method by comparing solutions for SIFs with ones obtained elsewhere, either analytically or numerically. a. no-Dimensional Problems In the test problem of two collinear cracks considered previously the errors in SIFs are on the order of 1% when spacings between cracks are on the order of lo-’ of the crack length. Note that such accuracy is achieved in spite of the fact that the interaction effect raises SIFs at the inner tips by 47%; i.e., it is quite significant. Even at spacings as small as 0.02 of the crack length (SIFs at the inner tips are increased more than by a factor of 2), the accuracy is still satisfactory for many purposes (on the order of 10%). Similar results hold for a periodic row of collinear cracks (see Kachanov, 1987); the error is 2.9%at the spacings of lo-’ of the crack length (when SIFs are increased by a factor of 2.2 by interactions) and 13% at the spacings of 0.025 of the crack length (when SIFs are increased by a factor of 4.1). These examples are not representative, though, since accuracy in the collinear arrangements is unusually good. In other geometries, accuracy is substantially worse; however, it still remains relatively good. It remains within several percent at spacings between cracks several times smaller than the crack lengths. The worst configuration is the one of partially shifted stacked cracks; in this case, the method remains accurate at spacings of about one-third of the crack lengths. b. Three-Dimensional Problems In 3-D problems, the accuracy is generally much better than in the similar 2-D ones. Referring to Kachanov and Laures (1989)for a detailed discussion, we review here the basic findings. Most of the 3-D solutions available in literature are limited to the case when the spacings between cracks are not too small so that the interactions remain relatively weak. Since our method is asymptotically exact in these cases (see discussion below), these problems do not constitute challenging tests. Comparison with the available results for moderate and strong interactions yields the following results. 1. The configuration analyzed (numerically)by Isida et al. (1985)consisted of parallel “offset” stacked cracks of elliptical shape under mode I loading. In those with a circular shape, the smallest spacing between

Elastic Solids with Many Cracks and Related Problems

295

cracks considered was 0.5 of the crack diameter; the ratios K,/KP were calculated for the “offsets” of 0 (axisymmetrical configuration), 0.5, 1.0 and 1.5 of the crack diameter. The calculated ratios K,/KP were, as read approximately from the graphs, 0.66, 0.83, 0.97 and 1.02. They fully coincide, within these digits, with the ones obtained by our method. 2. Uflyand (1967) obtained results for the axisymmetrical configuration of parallel stacked cracks under mode I loading, at the spacings between cracks of 0.25, 0.5 and 1.0 of the crack diameter. His results are KJKP = 0.7703, 0.8324 and 0.9191 whereas our results are 0.7678, 0.8249 and 0.9176. The disagreement is very small (and may be attributed partly to the procedure of numerical integration used by Uflyand: trapezoidal rule with 10 integration points). 3. Fabrikant (1987a, 1989) considered the problem of very closely spaced, strongly interacting coplanar cracks by reducing it to a new form of integral equations that are nonsingular and can be solved by rapidly converging iterations. For two coplanar cracks of equal size, the results converged up to spacings as small as 2.5 x of the crack diameter (mode I loading) and 0.005 (shear loading). Under mode I loading, the maximal error in SIF along the crack edge (at the point of closest spacing) is only 0.7% and 3.8% at the spacings of 0.05 and 2.5 x of the crack diameter, becoming indistinguishable at the points along the edge that are farther away from the point of the closest spacing. Under mode I1 loading, the results are similar (see Kachanov and Laures, 1989, for details). 6. Comparison with Polynomial Approximation Techniques

The advantages of the method are that (1) it applies to both 2-D and 3-D configurations with equal ease, being particularly accurate in 3-D, and (2)it is sufficiently simple to allow computer experiments on large arrays of interacting cracks, in both 2-D and 3-D (see Section V and VI). It is interesting to compare it with the frequently used 2-D technique of polynomial expansions of tractions on cracks and finding the polynomial coefficients from a system of linear algebraic equations. There are two basic versions of the technique of polynomial expansions: 1. Tractions on each considered crack are approximated by polynomials. 2. When considering tractions on a given crack, polynomial approximation is applied to tractions on the other cracks.

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Mark Kachanov

The best realization of technique 1 is achieved by using Chebyshev’s polynomials. (Gross, 1982). A less efficient realization-by using Taylor’s polynomials-was developed by Chudnovsky et al. (1983, 1984, 1987), Horii and Nemat-Nasser (1985,1987) who called this technique “the method of pseudotractions,” and other authors. Test problems involving collinear crack arrangements (considered in detail by Horii and Nemat-Nasser) show that the degree of approximating polynomials increases rapidly as spacings between cracks become smaller. The closest distance considered by them is one-quarter of the crack length; at this distance the polynomials’ degrees are 28 and 17 for the problems of two collinear cracks and a periodic row of cracks, respectively. The drawback of this technique is that the approximation of the crack-generated fields (having singularities at crack tips) by polynomials becomes inefficient at small spacings between cracks, close to the singularity points. Our method, in contrast, retains the singularities (in the “standard” stress fields). In technique 2, developed by Benveniste et al. (1989), polynomial approximations are applied not to the tractions on a considered crack, but to the tractions on the other cracks that generate additional tractions Atj’ on the considered crack. This technique has the advantage of retaining the singularities in the fields generated by the jth cracks. It appears to be more efficient, as demonstrated by applying it to the test problem of two collinear cracks: SIFs at the inner tips remained accurate at spacings as small as of the crack length. The main drawback of the polynomial techniques is that they are not easily extended to 3-D configurations. In principle, it can be done (polynomials of two variables will have to be used for approximation of tractions on cracks), but the method is expected to become cumbersome, particularly if interactions are strong or the number of cracks is substantial. To our knowledge, this technique has never been actually implemented in 3-D.

c. APPROXIMATIONOF SMALL TRANSMISSION FACTORS A N D APPROXIMATION OF

WIDELYSPACED CRACKS

We outline two approximations that can be formulated in the framework of our method. The first one (approximation of small transmission factors) applies to the situations when all the transmission factors A << 1. This may

Elastic Solids with Many Cracks and Related Problems

297

hold when the spacings between cracks are not too small, but may, nevertheless, depending on the geometry of the configuration, be smaller than the crack sizes. In this approximation, interactions produce only a weak impact on the average CODs (and, therefore, on the effective elastic properties), but may produce a strong impact on SIFs. The second one (approximation of widely spaced cracks) applies under a more restrictive geometrical assumption that spacings between cracks are much larger than crack sizes. Then, the impact of interactions on both effective elastic properties and SIFs is weak. In the first approximation, the method is considerably simplified; in the second one, the simplifications are so major that the results (first-order corrections for crack interactions) can be written down, with almost no calculations involved, for any arrangement of cracks both in 2-D and 3-D. 1. The Approximation of Small Transmission Factors (Interactions Weak in the Average Sense) We consider such crack configurations that the average traction vector (AtJi) induced on each ith crack site by each of the jth crack is much smaller than the traction induced on the ith crack by the remote loading 0': l(Atji) << lti(')l

for all i, j

(3.25)

If (3.25) holds, the interactions can be called weak in the average sense. Note that this definition deals with tractions. It is much less restrictive than the geometric requirement E = (crack

sizes)/(spacingsbetween cracks) << 1

(3.26)

and is, typically, satisfied at spacings between cracks that are comparable to crack sizes or even smaller (particularly, in the collinear and coplanar configurations). It follows from (3.25) that all 1) Aji 1) << 1

(3.27)

(absolute values of all the components of tensors Aji are << 1). Smallness of A-factors implies that, to within small values on the order of A, traction on the ith crack is a sum of the a'-induced traction n i * u Oand the tractions induced at the ith crack site by the other cracks, the latter being loaded by the uO-induced tractions nj- uo (rather than by the traction averages (t')).

298

Mark Kachanov

Therefore, instead of (3.9) in 2-D and (3.19) in 3-D we have

(3.28)

(3.29)

in the 2-D and 3-D cases, respectively. Note that this approximation can be interpreted as the first iteration of (3.9) and (3.19), i.e., as truncation of "feedbacks": transmission of the a'-induced tractions from the j t h crack on the ith crack is not followed by feedback. Thus, the major computational simplification in this approximation is that finding the transmission A-factors and the average tractions becomes unnecessary. This approximation is not as restrictive as it may seem: the inequality (3.25) applies to the average tractions and does not exclude the possibility of high local maxima of the tractions At(t) and the resulting sharp local peaks of the SIF-values along the crack edges. Moreover, up to relatively small spacings between cracks, the approximation of weak interactions may actually provide a reasonably accurate description of such peaks. The problem of two coplanar cracks serves as an example (see Kachanov and Laures, 1989). At the distance between cracks as small as 0.005 of the crack diameter the increase of the average traction due to interaction is only 8% (inequality (3.25)holds with a satisfactory accuracy) whereas the maximal value of K,/KP along the crack edge is 1.908. If the approximation of small transmission factors is used, this value changes to 1.842-a satisfactory estimate for many purposes. At the distance 0.05 of the crack diameter the increase of the average traction is only 5% whereas max K J K P = 1.296; this value changes insignificantly-to 1.281 if the approximation of small transmission factors is used. Another example is provided by the problem of two stacked cracks, where the applicability of the approximation is

Elastic Solids with Many Cracks and Related Problems

299

restricted by substantially larger spacings; this approximation results in a 5% error in SIFs only if the spacings between cracks are at least 1.25 and 0.35 of the crack diameter for the normal and shear loadings, respectively. Thus, the interactions may or may not be weak depending on the physical property considered: interactions that are weak in the sense of traction averages are not necessarily weak in the sense of SIFs. This fact has an important implication: the efectioe elastic moduli for a solid with a given arrangement of cracks may differ only slightly from the ones obtained in the approximation of noninteracting cracks, whereas SIFs-fracture-related properties-may be significantly affected by interactions. This serves as yet another illustration of the fact (discussed in Section VII) that there seems to be no stable quantitative correlation between deterioration of the efective elastic stirness of the “damaged” material and its progression toward failure. 2. The Approximation of Widely Spaced Cracks This approximation is defined by quite a restrictive inequality (3.26)-a condition of a geometrical nature. Note that many of the results available in literature have been obtained under this assumption. In this approximation, our method yields solutions (first-order corrections for crack interactions) for arbitrary arrangements of cracks, in both 2-D and 3-D, in an elementary way, with almost no calculations involved. We note, first, that (3.26), obviously, implies that (3.25) is satisfied, so that all the simplifications of the approximation of small transmission factors apply. Moreover, further major simplifications follow. Since the spatial gradient of a crack-generated field attenuates with distance faster than the the impact of the ith crack on the kth one can be characterized, to field within small values of higher order, by the stress that is constant along the kth crack site and can be taken as the value of the ith crack-generated field at the kth crack center. Thus, the only calculation involved is finding the stresses generated by ith cracks (uniformly loaded by the a’-induced tractions n’. 0’). An additional simplification is that, instead of the standard fields, their farfield asymptotics given by much simpler expressions (Section 1I.C) can be used. Note that the interaction correction for a SIF on a given crack depends on the size of the other cracks but not on its own-there is no “feedback” in the framework of the asymptotic solutions (see examples b and d to follow). Several configurations are considered below, as an illustration.

300

Mark Kachanov

a. l b o Coplanar Cracks of Equal Radius a Under Tensile Remote Loading Here, the distance between the crack centers 2b >> a. Taking the far-field asymptotics of the a,,-component of the standard mode I field and simply adding it to the aO-inducedtraction, one obtains K, =~ ; [ + i (a/b)3/12.3

(3.30)

The second term in the brackets is the first-order correction for crack interaction. This result recovers the one obtained by much lengthier means by Collins (1962). b. %o Coplanar Cracks of Diferent Radii, a, and a,, Tensile Loading Here, the distance between crack centers 2b >> a,, a,. Following the same steps, i.e., evaluating the asymptotic far field generated by crack l(2) at the center of crack 2(1), one obtains = K(1)o I [l

+ (~,/b)~/l2n],

K12’ = K{”O[l

+ (al/b)3/12~]

(3.31)

c. Wo Stacked Cracks of Equal Radius a, Tensile Loading Here, the distance between crack centers 2b >> a. The asymptotic expression for the stress u,, generated by a crack loaded by a uniform pressure p at the far away point b above its center is oZz= -p(2/3n)(b/a) so that KI = KP[l - (2/3~)(a/b)~]

(3.32)

where the minus sign indicates that the effect of interaction is shielding. d. Wo Stacked Cracks of Diflerent Radii under Mode I Loading, Tensile Loading Here, the distance between crack centers 2b >> a,, a, KI1) =

K(1)o I [l - (2/3~)(a,/b)~],

Ki2’ = K”” I c1-

(3.33)

e. lnjinite Stack of Cracks of Equal Radius a, Tensile Loading Here, the distance between crack centers 2b >> a:

[ + (y+ (y ***I

K, = KF[l -(2/3~)(a/b)~] 1 KI = KP[l - (2/3~)(a/b)~]

-

-

+

(3.34)

Elastic Solids with Many Cracks and Related Problems

30 1

where c(3) = 1.202 is the zeta-function of argument 3. Some of these results recover solutions obtained earlier in the literature by much lengthier means. f. Limits of Applicability of the Asymptotic Solutions

Because of the elementary character of these solutions, it is of interest to estimate the limits of their applicability. We note that a characteristic feature of the solutions obtained in the approximation of widely spaced cracks is that SIFs are constant along the edge of each crack (in the 2-D case, they are the same for both crack tips). This indicates a very limited usefulness of such solutions-the results are valid only in the limit of vanishingly weak interactions; see Kachanov and Laures (1989) for discussion and estimates of applicability.

IV. Various Effects Produced by Crack Interactions Using the method of analysis outlined in Section 111, we discuss various effects produced by interactions of cracks. In this section, we focus our attention on SIFs (effective elastic properties are discussed in Section VI). Solutions of various interaction problems were obtained by the method described in Section 111.

A. STRESS SHIELDING AND STRESSAMPLIFICATION. Two- AND THREE-DIMENSIONAL INTERACTIONS Crack interactions may produce either stress amplification (increase of SIFs) or stress shielding (decrease of SIFs),depending on the geometry of the configuration and, for the same geometry, on the mode of loading. Here, we examine these effects by analyzing several representative geometries. 1. 2-0 Geometries

a. Mode I Loading Collinear configurations are characterized by the amplifying effect of interactions (although the amplifying effect is the strongest when the symmetry is slightly “disturbed,” see the discussion in Section C). This is

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Mark Kachanov

1.6 0

a

t

t

t p t

1

1

1

1

1

t \ 0.1

0.5

0.9

1.3

2.1

1.7

FIG.14. Two collinear cracks under mode I loading. SIF at the inner tip.

illustrated in Fig. 14 for the collinear configuration of two cracks of equal length. Stacked conjiyurations, on the other hand, constitute a shielding configuration, as illustrated in Fig. 15. The amplifying and shielding effects of several neighbouring cracks on a 1.o

0.8

0.4

-

i

-1.1 1

1

1

1

1

0.0 0.2

0.5

0.8

1.1

1.4

1.7

2.0

A/] FIG.15. SIFs for two stacked cracks under mode I loading.

Elastic Solids with Many Cracks and Related Problems

303

given crack may compete. The overall effect in such cases depends on the relative distances from the considered crack tip to the amplifying and shielding neighbors. Figure 16 serves as an illustration. Figures 14-16 show that the effect of shielding has a longer range than that of amplification: in the configurations where they compete, the effect of shielding is dominant; i.e., to cancel the impact of shielding neighbors on a given crack tip, the amplifying neighbor should be much closer to the tip. This is a consequence of the structure of the a,,-field associated with one crack under mode I loading: there is a compact amplification zone (a,, > 0) and a substantially larger shielding zone (ayy< 0), see Fig. 1. b. Mode I1 Loading Many configurations that produce the shielding effect under mode I loading become amplifying under mode I1 loading. Figure 17 provides an illustration. 2. Relative Strength of Interaction Efects in 2 - 0 and 3 - 0 Geometries

The 3-D interactions produce effects that are qualitatively similar but substantially weaker than in the similar 2-D configurations: coplanar 2.0

1.5

I

' .

'

.

' I '

'1i @//

0.0 0.0

0.25

'

1

"

' .

'

7

,

0.5

a

'

t

r

'

'

'

tPt

h T I rC.

0.75

.

I

:

f

1.0

Fic. 16. Competition of the amplification and shielding effects (mode I loading) for the inner tips: + and - signs indicate the regions where the amplification and shielding are dominant, respectively; the neutral line (no interaction effect)is shown. Note that the amplifying effect of the collinear interaction has a much shorter range than the shielding effect of the stacked configuration: A must be much smaller than h to neutralize the shielding effect.

Mark Kachanov

304

1.0 0.0 1

"

: 0.5

"

"

"

"

"

1

"

1.5

"

2.0

h?: FIG.17. The same configuration under mode I1 loading (h = I ) .

interactions produce stress amplification whereas stacked ones produce shielding. Similarly to 2-D cases, the shielding interactions under mode I loading have a longer range than the amplifying ones. Figures 21-24, which will appear in Section B, provide an illustration. The interaction efects in 3 - 0 are weaker than in similar 2-D geometries, as illustrated in Fig. 18, which directly compares the strengths of interaction effects in 2-D and 3-D. The difference in strength of the interaction effect depends on the geometry: in configurations of the shielding type (stacked cracks) the difference is moderate and decreases at smaller spacings between cracks; in the amplifying configurations (collinear and coplanar cracks) the difference is very substantial, particularly for closely spaced cracks. For example, in the 3-D configuration of two coplanar cracks, the maximal (along the crack edge) increase of K , is about 30% at the spacing between cracks of 0.05 of the crack size, vs. about 80% for the similar 2-D configuration of two collinear cracks with the same spacing. These facts are directly related to the structure of single crack-generated fields (discussed in Section 11): the field of oyyunder mode I loading extends over comparable distances in the y-direction, in 2-D and 3-D geometries, but attenuates substantially faster with distance in the x-direction in the 3-D geometry.

Elastic Solids with Many Cracks and Related Problems

305

1.8

i l

t

t

t

t p t

t

t p t

1.4 0

LT

\ 1.0

b7 0.6 1

0.2 0.0

1

1

1

0.5

a/2e

1

1.o

1

1

1

1.5

FIG.18. Comparison of interaction effects in similar 2-D and 3-D configurations.

3. Localized Character of 3 - 0 Interactions. Mixed Mode Efects

The 3-D interaction effects vary along the crack edges, and changes in SIFs produced by interactions are usually localized within a relatively small zone. This is illustrated in Fig. 19, which shows variation of the mode I SIF along the edges of two coplanar cracks. The results of Section V on the interaction of a crack with microcracks provide further examples: SIFs along the main crack front are affected by microcracks only in the immediate vicinity of the microcracks. An additional complicating factor is that both modes I1 and I11 are present,

FIG.19. Interaction of two coplanar circular cracks (spacing between cracks is 0.05 of the crack diameter): the solid line shows variation of the SIF along the crack edge.

Mark Kachanov

306

t t t t

1 1 1 1

FIG.20. V-configuration:modes I, I1 and I11 SIFs along the crack edge (SIFs are normalized to their values in absense of interactions, dashed line).

if shear tractions are applied. Figure 20 shows interaction effects in the configuration of two closely spaced inclined cracks (V-configuration),where all the modes are present along the crack edges. An interesting feature of this configuration is a strong mixed mode interaction. Indeed, comparison with two coplanar cracks (having the same spacing between cracks) shows that, although the absolute value of the maximal K, is 55% higher in the coplanar configuration, the increase of max K , due to interactions in the V-arrangement is 1.68 times, vs. 1.30 times in the coplanar configuration. Thus, the interaction effect is much stronger in the V-arrangement. This is explained by the mixed mode interaction: stress field generated by the shear mode on crack 1 enhances the model SIF on crack 2.

B. RANGEOF INFLUENCE

OF A CRACK IN AN

ARRAYOF INTERACTING

CRACKS

We discuss here the range of influence of an individual crack in a crack array. We consider two periodic arrangements of cracks: a collinear (coplanar) one and a stack of parallel cracks. Then, we create a “disturbance”

Elastic Solids with Many Cracks and Related Problems

307

I

0.9

1

2

3

4

Crack Number FIG.21. Changes in SIFs (marked by stars) in a periodic collinear row of cracks generated by a “disturbance.” SIFs are normalized with respect to the one of the undisturbed configuration. (Spacing between cracks in the undisturbed configuration is one-third the crack length.)

(by either removing one crack or rotating it) and examine the zone of influence of this disturbance; i.e., the number of closest neighbors affected. 1. Zone of Influence in 2 - 0

a. Zone of Injluence in the Collinear Direction We consider a collinear crack array with a “disturbance” created by rotating one crack by 45” and calculate the change in SIFs on neighboring cracks caused by the disturbance. Figure 21 shows that the disturbance has a short range of influence: its impact is limited to the closest one or two cracks. b. Zone of InfIuence in the Direction Normal to a Crack A column of parallel cracks is considered; one crack is then removed from the stack. The results (Fig. 22) show that, similarly to the case of collinear array, the disturbance has a short range of influence, confined to the closest one or two neighbors.

2. Zone of Influence in 3 - 0 a. Zone of Influence in the Coplanar Arrangement A row of 11 coplanar cracks is considered, and a “disturbance” is created by rotating a median crack by 45”. The maximal (along the crack edges)

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Mark Kachanov

FIG. 22. Changes in SIFs in a column of cracks generated by a “disturbance.” (Spacing between cracks in the undisturbed configuration is one-half the crack length.)

changes in SIFs at the neighboring cracks are shown in Fig. 23. The range of influence of the disturbance is even shorter than in the 2-D case-its impact is practically confined to the closest neighbor. b. Zone of Influence in the Direction Normal to a Crack A stack of 11 parallel cracks is considered, and a “disturbance” is created by removing a median crack. The results are shown in Fig. 24. Similarly to the previous case, the impact of disturbance is practically confined to one or two closest neighbors. C. EXTREMAL PROPERTIES OF SLIGHTLY ASYMMETRIC ARRAYS

An interesting (and somewhat unexpected) observation is that the interaction effect may be maximal not in the ideally symmetric arrangements but in configurations where the symmetry is slightly disturbed. The simplest example that explains the underlying physical mechanism is the configuration of two collinear cracks loaded under mode I loading: if the right crack is rotated about its center on an angle f#J (Fig. 25), the mode I SIF at the inner tip of the left crack is maximal not at f#J = 0 (as may be intuitively expected) but at x 15”. The reason is that K,at left crack tip is affected by both normal and shear tractions on the right crack (shear traction appears as a result of asymmetry). The impact on K , of the normal traction on the right crack is, obviously, f#J

Elastic Solids with Many Cracks and Related Problems

0.8

309

1

2

3

4

5

Crack Number

FIG.23. Changes in (maximal, along the edge) SIFs in a 3-D periodic coplanar row of cracks generated by a “disturbance.” [Spacing between cracks in the undisturbed configuration is onethird the crack diameter.)

maximal at Cp = 0, but this implies that its rate of change with Q, is zero at Q, = 0 so that the decrease of this impact due to rotation is small at moderately small 4. On the other hand, the impact on K, of the shear traction on the right crack has a nonzero rate of change at Q, = 0. Therefore, the combined impact of both modes is maximal at nonzero Q,. Thus, the underlying mechanism of this phenomenon is the appearance of mixed mode interactions caused by a disturbed symmetry. It is clear,

1.05

\ 1.025

x-

m 10

1

2

3

y 4

5

Crack Number FIG.24. Changes in SIFs in 3-D periodic stack of parallel cracks generated by a “disturbance.” [Spacing between cracks in the undisturbed configuration is one-half the crack diameter.)

Mark Kachanou

3 10

0.0 0.0

30.0

60.0

90.0

d FIG.25. SIFs at the inner tip of the left crack in the collinear configuration with symmetry disturbed by rotation.(Spacing between cracks in the undisturbed configurationis onetenth the crack length.)

therefore, that the phenomenon is general: the “disturbance” of symmetry that gives rise to mixed mode interactions intensifies the interaction effect (if the disturbance remains moderately small). In the case of collinear cracks, for example, disturbances of symmetry ocher than rotations (Fig. 26) lead to a similar intensification of interactions. One can easily construct a number of similar configurations (for example, a rectangular periodic array with slightly disturbed crack orientations or positions). The excess of SIFs in configurations with disturbed symmetry over their values in ideally symmetric configurations is quite noticeable, as seen from the preceding examples. Note that the corresponding reduction of the critical load at which the affected crack tip will propagate becomes even more noticeable if the appearance of mode I1 at the tip (in the disturbed configuration) is also taken into account. A similar phenomenon holds in 3-D configurations. It is less pronounced (due to a general weakness of all interaction effects in 3-D), but has many more manifestations (due to a larger variety of possible geometrical asymmetries). The crack-microcrack configuration of Fig. 36 (in Section V) provides an illustration: the peak of SIF is found not at the symmetry point of the crack front where it may be expected, but at a somewhat shifted position (particularly at 6/a = 0.8); this effect is, again, due to the mixed mode interactions appearing at asymmetric points. These observations on extremal properties of slightly asymmetric

Elastic Solids with Many Cracks and Related Problems

31 1

1.6 1.4

1.2

1.o

0.8 0.6

1

0.0 -0.2

0.0

0.5

1.0

1.5

2.0

A/1 FIG. 26. SIFs at the inner tip in a collinear configuration with symmetry disturbed by translation.

configurations may have some physical implications (although such considerations remain speculative at this point). If one assumes that the system tends to an extremum of the energy release rate (and, thus, of the SIFs), then the initially symmetric configurations will tend to deviate from symmetry in the course of crack propagation, to pick up the mixed mode interactions that increase SIFs. For example, in the configuration of two collinear cracks loaded in mode I, the cracks d o not grow toward each other along the straight line (under mode I loading) but deviate from it, giving the appearance of “avoiding each other.” This problem was discussed by Melin (1983), with a rather complex mathematical discussion involved. It seems that a simpler explanation may be suggested: deviation from symmetry leads to mixed mode interactions that maximizes the energy release rate. Asymmetry of some naturally occurring crack patterns may, possibly, be explained in the same way.

D. INTERSECTING CRACKS(TWO-DIMENSIONAL CONFIGURATIONS) 1. intersecting Cracks

The configurations of intersecting cracks may be of interest in a variety of applications, both micromechanical and structural. Kachanov and Montagut (1989) demonstrated how the methnd of analysis of crack interactions

312

Mark Kachanov

outlined in Section I11 can be used for an approximate analysis of such configurations. We apply this method to intersecting cracks by simply ignoring the intersection and treating the “overlapping” cracks according to the general scheme for interacting cracks. Formally, this creates no difficulties in the computational scheme, and SIFs at the outer tips can be found. (Obviously, stress concentration at the point of intersection cannot be analyzed by this technique). The author is unable, at this point, to rigorously justify this procedure; the only justification is that it works surprisingly well for the available test problems. Results for two such test problems are presented in Fig. 27. a. Starlike Configuration The solution obtained by formally applying the method of Section I11 and ignoring the intersection is compared with the exact solution in Fig. 27. The comparison shows that the agreement is very good, up to the number N of cracks in the star of about 20. Note that the actual reason for increasing

1.0

0.8

-

r-

0.6

c

v r

0.4 0.2

0.2 0.0

0.0

2

4

6

8 10 12 16 20

n

0.0

,

I 0.2

,

I 0.4

,

I 0.6

,

I ( 0.8

1.0

Wa

FIG.27. Test problems for intersecting cracks: comparison of our solution (solid line) with the exact results (dashed line).

Elastic Solids with Many Cracks and Related Problems

313

errors at N > 20 is that the crack tips become too close to one another for the method to remain accurate; it is unrelated to the fact of intersection. b. Rectangular Cross The agreement is, again, quite good. This simple approach is no't restricted to any particular symmetric arrangement and can be applied to any nonsymmetric configuration formed by intersecting cracks (and holes; see Kachanov and Montagut, 1988). 2. Crack Touching the Line of Another Crack A somewhat different configuration-with the tip of one crack touching the line of another crack-was considered by Benveniste et al. (1989).Their analysis is based on (1) finding SI[Fs at the tips of very closely spaced cracks by expansions of tractions on cracks into Legendre's polynomials, combined, possibly, with step functions and (2) using these obtained solutions for the outer tips as an approximation of the SIFs at the outer tips of the original configuration. Of the three test problems (a T-crack and two loadings of an H-crack), the accuracy was satisfactory in one of the problems; in the other two problems, the accuracy was satisfactory provided the sizes of cracks were not too different (their ratio not exceeding 5-6 in one configuration and 2.5 in the other). We note that, in the limit when spacings between cracks approach zero, such solutions should indeed converge to the ones with touching cracks. However, this convergence is extremely slow. Consider, as an example, a configuration of two collinear cracks of equal length. In the aforementioned limit, the SIF at the outer tip should increase $ = 1.41 times, as compared to the case of one isolated crack (since crack size increases two times when cracks coalesce). The exact solution of this problem shows that, when the spacing A between cracks is as small as of the crack length, the increase is only 1.28 times, increasing to only 1.32 even when A = spacings on the order of lo-" of the crack length (at which polynomial techniques may become inefficient) are required for a close approach to the $ increase. We note, also, that the configuration of two collinear cracks is the simplest one, and approximation methods, generally, show the best accuracy when applied to this problem. Therefore, for the results for touching cracks obtained by this technique to be reliable, consideration of extremely closely spaced cracks may be necessary.

314

Mark Kachanov E. INTERSECTING CRACKS (THREE-DIMENSIONAL CONFIGURATIONS)

The same technique can be applied to three-dimensional configurations of intersecting (penny-shaped) cracks. Unfortunately, no test solutions seem to exist, so that the accuracy of the technique cannot be verified. However, the 3D problems are, generally, less sensitive to simplifying assumptions; the technique, therefore, can be expected to work, generally, better than in 2-D. The restriction remains, of course, that stress concentrations near the line of intersection of crack planes cannot be analyzed by this technique (similarly to the 2-D case, where the stress concentration near the point of intersection could not be analyzed). Another restriction is that the edges of two cracks cannot have common points (this would have created a nonintegrable singularity in expressions for SIFs). Here, results are given for two 3-D configurations: a crack intersected, near its center, at a 45” angle, by a crack three times smaller than it (Fig. 28), and two cracks of equal size intersecting at a 45” angle along a half-diameter (Fig. 29). In the configuration of Fig. 28, SIFs along the edge of the larger crack are almost unaffected by the presence of a “ripple” near its center; the SIFs along

__.. -- .___ ,_....__

FIG.28. SIFs along the edge of the (smaller) crack in the 3-D configuration of intersecting cracks. Remote tension normal to the larger crack is applied. The ratio of the crack sizes is 1/3. SIFs along the edge of the larger crack are almost unaffected by the presence of a “ripple” near its center. SIFs are normalized to their values for an isolated crack of the same orientation.

Elastic Solids with Many Cracks and Related Problems

315

B

FIG.29. SIFs along the edge of crack 2 in the 3-D configurationof intersecting cracks (of equal size). Remote tension normal to crack 1 is applied. SlFs are normalized to their values for an isolated crack of the same orientation.

the edge of the smaller crack experience a strong shielding (shown in Fig. 28) at all points of the crack edge, due to the presence of the larger crack. In the configuration of Fig. 29, SIFs along the edge of crack 2 are shown; they experience shielding in the zone of overlapping and almost no effect of interactions outside of this zone. In both configurations, the SIFs are normalized to their values for an isolated crack (dashed line). The results may not be reliable in the vicinity of the line of intersection of the crack planes.

F.

INTERACTION OF CRACKS

FILLED WITH COMPRESSIBLE FLUID

We analyze the situation when crack cavities are filled with a compressible fluid. It is assumed that the fluid is nonviscous; i.e., it resists compression but does not resist shear motions of the crack faces. This situation may be of interest for the mechanics of fluid-saturated geomaterials. We assume the “undrained” conditions, i.e., that the total mass of fluid in each cavity remains constant; if fluid diffusion across crack faces does take place, this approximation corresponds to a “short time” response. (In the opposite limit of “drained” approximation, when crack cavities freely

316

Mark Kachanou

exchange fluid with the surroundings, the mechanics of crack interactions is the same as in the case of dry cracks.) The analysis of this section focusses on the fluid’s impact on stress interactions, in particular, on SIFs. (Efectiue elastic properties of a solid with fluid-filled cracks and pressure polarization are discussed in Section V1.E.) First, the behavior of one fluid-filled crack is analyzed; the consideration is similar to the analysis of Budiansky and OConnell (1976). Then, crack interactions and their coupling with fluid pressures are analyzed, using the method of Section 111. 1. One lsolated Crack

If fluid is present in a crack cavity, and to = ( p o , r o ) is the traction corresponding to the remote loading, then the overall normal traction on crack faces is

+ Aq,

p = po

T = TO

(4.1)

where Aq is the fluid pressure (that develops as a reaction to the applied normal traction). Its sign is opposite to the sign of po and thus Aq has a “dampening” (counteracting) effect. The value of Aq is determined by relating it, through a constitutive equation of the fluid, to the change of density of the fluid, which, in turn, is related to the change in the cavity’s volume. For simplicity of calculation, we assume that the cavity has the shape of a relatively thin platelet, so that its normal compliance can be approximated by that of a crack. We first consider the case of a cavity circular in plane of radius 1 that, in the absence of applied stresses, has average opening ( b , ) and volume n13c,, where lo= (b,)/l can be called the auerage aspect ratio. Since the cavity is thin, its volume change is due mainly to changes in ( b , ) ( I remains approximately constant). Thus, the relative volume change of the cavity is AVIV, = ( A b J / ( b , ) . Since, under undrained conditions, the fluid mass within a cavity is constant: qoV, = ql! the change of fluid density is A‘tl‘lo = -AV/Vo = -
(4.2)

The corresponding change of fluid pressure is given by the constitutive equation for a compressible fluid, which, in the linearized formulation (small density changes), has the form W

l

O =

-uAq

(4.3)

where u is the compressibility of a fluid (generally, a function of q and temperature; treated as a constant in the considered linearized approxima-

Elastic Solids with Many Cracks and Related Problems

317

tion); in conjunction with (4.2), this equation relates Aq to the change of opening (Ab,,). On the other hand, (Ab,) is related to the overall normal traction on a cavity p o + Aq by a “cavity compliance” relation: (AbJ = (PVEoXpO -t A d

(4.4)

where the compliance of a (thin) cavity is taken to be approximately the same as the one of a circular crack of the same diameter: p = 1q1 - v , 3 / 3 ~ In . the 2-D case (narrow elliptical holes of length 2/), B = n/. These equations also yield the change of fluid pressure induced by the applied traction PO:

where

s = p-’KEo[o

(4.6)

is the key constant of the problem that determines coupling between fluid pressure and applied stress. It is similar to the one used by Budiansky and O’Connell. Physically, (4.4) means that the applied compressive stress is counteracted by two factors: the “cavity’s stiffness” and the fluid pressure. Parameter 6 determines relative shares of these two factors. In the limit of highly compressible fluid (K -+ 00, “air”), the change in the fluid pressure in cavities caused by applied stresses is 0, and the case of a dry crack is recovered. In the opposite limit K + 0 (incompressible fluid), Aq = --po and the crack is fully constrained against normal opening; the same is true if K is finite but cavities are infinitesimally thin, lo -+0, indicating that coupling between stresses and fluid pressure is stronger for thinner cracks. As an example that may be relevant for fluid-saturated rocks, we consider MPa-’ (water) and E , x 6 x 10” MPa (granite). the case of K = 0.5 x Then, for the cavity aspect ratios lo < 0.006 the impact of fluid is so strong that the normal COD constitutes less than 10% of that of a dry crack. The impact of fluid becomes small (COD differs by less than 10% from that of a > 0.5-0.6 (note that medium with dry cracks) only for very wide cavities, lo the calculation of the cavity’s volume change used earlier becomes then inaccurate). Thus, in the entire range of interest [,, < 0.5, the effect of stress-fluid pressure coupling is strong.

318

Mark Kachanov

2. Interacting Cracks Here, we analyze some physical effects produced by coupling between stress interactions and Jiuid pressures. The basic observation is that normal and shear loading modes on cracks play different roles in the coupling. Since the fluid does not resist shear CODs, mixed mode interactions of the type shear-shear and shear-normal (abbreviated as s - s and S - n ) are unaffected by the fluid, whereas interactions of the type n -+ s and n -+ n are “dampened.” For brevity, we combine, in the 3-D case, both shear modes T and s, into one (in order to use, instead of (3.20),the shorter formulas (3.10)). The formulas (3.10) that interrelate averages tractions in dry cracks, are to be modified as follows:

where, in the spirit of (4.9, we have

so that equations for the average tractions take the form

We observe that fluid produces “dampening” effects of two kinds: (1) it reduces the overall traction on a given cavity, as described by (4.1), independently of interactions, and (2) it dampens the interactions, in the modes n - s and n + n . Another observation is that both (1) and (2) are dampened to the same extent, as shown by the common dampening multiplier (1 ai)The first equation of (4.9)can be rewritten in a form that resembles the one for dry cracks; the difference is indicated by overbars:

+

’.

(4.10)

Elastic Solids with Many Cracks and Related Problems

3 19

(4.11)

Note that the transmission &-factors have the structure of products (geometrical factor A) x (damping factor). In the limit of S -,0 (incompressible fluid or very thin cavities), (pi) = 0 and

(fi) = fi(0)

+ 1 Ajf(~j)

(4.12)

j+i

indicating that the normal mode on cracks is fully suppressed,and only shear interactions (unaffected by fluid) take place. In the opposite limit of 6 + CO (“air” or wide cavities), the case of dry cracks is recovered. a. Impact of Fluid on SIFs of Interacting Cracks According to the method of Section 111, the actual (variable)tractions on a given crack are found from (3.9), as a sum of the no-induced tractions and the impact of the other cracks loaded by the average tractions on them. Applying this superposition to our case, we represent the mode I SIFs on a given crack in the form K , = KP,dlY

+ KP.ICaC1 +

KP

(4.13)

where the first term is the SIF of an isolated dry crack, the second term characterizes the reduction of SIF due to the fluid pressure arising in an isolated crack as a reaction to the applied stress and the third term represents the interaction effect(partly dampened by fluid, as discussed above). In shear modes, the second term is absent: (4.14)

An important observation is that fluid dampens both amplifying and shielding interactions. b. Periodic Row of Collinear Cracks This simple 2-D configuration illustrates the mechanics of stress interaction-fluid pressure coupling. Under mode I1 loading, fluid has no impact on interactions, and the problem has the same solution as for dry cracks. Under

320

Mark Kachanov

mode I loading, the equation for the average normal traction (the same on all cracks) has the form ( p ) = 6(1 + 6 ) - ' p o

+ 6(1 + d)-' C A(k)(p)

(4.15)

where A(k)is the transmission factor characterizing interaction of a given crack with the kth neighbor; thus, (4.16) Assume, for illustration, that parameter 6 = 1, and that the spacing between cracks is one-half of the crack length. Then, denoting by KF the SIF for an isolated dry crack (reference value), we obtain that, for an isolated Juid-jlled crack, K , = 0.50, fluid strongly dampens the SIF. This represents the first mechanism through which fluid affects SIFs. The second mechanism is the impact of fluid on interactions: for interacting fluid-filled cracks, K , = 0.56, interactions increase the SIF by 12% It is interesting to compare this increase due to interactions to the one for dry cracks: for the latter, interactions increase the SIF by 29%. Thus, fluid significantly dampens the interaction effect. In this example, interactions have an amplifying effect, and their dampening means reduction of the SIF. In the configurations when interactions have a shielding effect (for example, stacked cracks), their dampening by fluid means an increase in the SIF.

G. INTERACTION OF CRACKS IN AN ANISOTROPIC MATRIX This section is a brief summary of the work of Mauge and Kachanov (1990,1992) and Mauge (1993), where the stated problem was investigated in detail (in the 2-D case). The method of Section I11 was used; in the available test problem (two inclined cracks) the method's accuracy remained high at the spacings between cracks as small as 0.05 of the crack length. The "standard" stress fields generated by uniformly loaded cracks are significantly affected by the matrix anisotropy. Therefore, the transmission Afactors are functions not only of the geometry of the crack array (as in the isotropic case), but on the matrix moduli as well. Our analysis is restricted to the case of an orthotropic matrix when solutions for interacting cracks of arbitrary orientations can be obtained in closed form (for a nonorthotropic matrix, the basic procedure remains

Elastic Solids with Many Cracks and Related Problems

32 1

unchanged, but solutions involve a numerical procedure of solving a fourthorder algebraic equation). With the exception of the problem of collinear cracks (when the interaction problem is identical to that for the isotropic matrix), the interactions are affected by the matrix anisotropy. Three parameters that affect the interactions are the ratio of Young’s moduli E J E , in the principal directions of orthotropy, the shear modulus G I , and Poisson’s ratio v I 2 . Of these parameters, the ratio E J E , plays the dominant role. If E,/E, > 1 (or < l), then interactions under a uniaxial loading in the x2 direction are enhanced (or weakened) by the matrix anisotropy, i.e., are more (less) intense, compared to the case of isotropy. For example, the shielding effect for stacked cracks is enhanced (or weakened) if matrix stiffness in the direction normal to cracks is higher (lower) than in the perpendicular direction. This has a clear physical explanation: transmission of stresses in a direction of higher (lower) stiffness is more (less) “efficient.” Note that the impact of the ratio E J E , is strongly “asymmetric”; enhancement of the interaction effects is much stronger than their weakening. The impact of the shear modulus G,, becomes noticeable only when this modulus is small (compared to the smallest of Young’s moduli). Impact of Poisson’s ratio v l t on crack interactions is small. The problem of intersecting (at a 90” angle) cracks in an orthotropic matrix was also analyzed, using the approach of Section 1V.D (such crack configurations in an orthotropic matrix may be of interest for the mechanics of composites). It was found that, in the case of sufficiently high contrast between matrix stiffnesses in two perpendicular directions, SIFs at the tips of one of the cracks may be negative under the applied hydrostatic tension.

V. Interaction of a Crack with a Field of Microcracks A. INTRODUCTION

Microcracking accompanies crack propagation in many brittle materials (see, for example, observations of Han and Suresh (1989) on high-temperature fracture of ceramics). This may substantially affect the overall mechanics of fracture propagation.

322

Mark Kachanov

There are several physically different mechanisms by which microcracking may affect the overall resistance to fracture propagation. Among them 1. Expenditure of energy on nucleation of microcracks near the main crack.

This may (or may not, depending on strength of the intergranular cohesion, the level of residual stresses and other factors) constitute a significant energy “sink” and thus noticeably increase the apparent fracture toughness. 2. Performation of the material. The crack path passes through material only partly; another part of it passes through empty space. This factor reduces the apparent fracture toughness. 3. Release of residual stresses. 4. Elastic interaction of the main crack with microcracks that changes the stress intensity factors at the main crack. A number of papers have suggested that such an interaction produces stress shielding; i.e., reduces SIFs at the main crack tip. This result was obtained, in most cases, by modelling the microcracked zone by an effective elastic material of reduced stiffness. This work analyzes mechanism 4 only. In particular, we discuss whether mechanism 4 leads to an increased resistance to fracture propagation (“toughening by microcracking”)-a phenomenon suggested in a number of papers. We also discuss whether modeling the microcracked zone by an effectivehomogeneous material of reduced stiffness is adequate. We first consider several simple geometries involving one or several microcracks and then examine the effects produced by large arrays of randomly located microcracks: these arrays represent samples of certain microcrack statistics. In the literature, a number of solutions (analytical and numerical) have been obtained for relatively simple configurations involving one or several (symmetrically located) microcracks, in 2-D (Turska-Klebek and Sokolowski, 1984; Chudnovsky et al., 1984; Rubinstein, 1985, 1986; Rose, 1986; Hori and Nemat-Nasser, 1987; Kachanov and Montagut, 1986; Fischer, Maurer, and Daves, 1988; Dolgopolsky, Karbhari, and Kwak, 1988; Gong and Horii, 1989) and in 3-D (Laures and Kachanov, 1991). “Optimal” 2-D configurations involving one or two microcracks that provide maximal shielding were considered by Shum and Hutchinson (1990). The asymptotic 2-D case of very small spacing between crack tips was analyzed by Horii and Nemat-Nasser (1987) by power series expansions in terms of ratios of the spacing between crack tips and the microcrack size to

Elastic Solids with Many Cracks and Related Problems

323

the size of the macrocrack. Their approach seems to be limited to the case of a finite main crack. A n alternative approach to the same asymptotic situation (which can be considered as complementary to the aforementioned one) was developed by Gorelik and Chudnovsky (1992); it was applied to the case of a semi-injinite main crack (microcracks are embedded into the crack tip field of the macrocrack). From the physical point of view, interactions with large microcrack arrays that represent certain microcrack statistics are of primary interest. In this respect, several relevant works should be mentioned. Hoagland and Embury (1980) were, probably, the first to consider interaction of a crack with a large microcrack array; they performed several computer simulations. The limitations of this work are that the analysis was two-dimensional, the microcrack array was assumed ideally symmetric with respect to the main crack (so that some important effects produced by stochastic asymmetries in the microcrack field were missed, see discussion later) and the procedure of evaluating tractions on microcracks seems to implicitly assume that the interactions are weak. Tamuzh and Romalis (1984) considered a 2-D problem of a crack interacting with an infinite doubly periodic system of two families of parallel microcracks; the results were obtained for sufficiently wide spacings between cracks when the interactions are weak. Romalis and Tamuzh (1988) analyzed a 3-D problem of a penny-shaped macrocrack interacting with penny-shaped microcracks; their iterative procedure assumes that the distance between a current point M on the macrocrack and a current point on a microcrack can be identified with the distance between M and the microcrack center, which may yield substantial errors at close spacings between cracks; actual results (obtained with interactions between microcracks being neglected) were reported for several simple geometries that do not represent physically realistic microcrack statistics. Chudnovsky and Wu (1990) considered a special case of an extremely dense 2-D array of parallel microcracks and gave further analysis in terms of continuous distributions of the microcracks openings (1991). Substantial literature exists on modelling the microcracked zone b y an “equivalent” homogeneous elastic material of reduced stiffness; see, for example, Buresch (1984), Clarke (1984), Evans and Fu (1985), Charalambides and McMeeking (1987), Laws and Brockenbrough (1987), Ortiz (1987), Hutchinson (1987), Ruhle et al. (1987); such modelling was used by Gong and Meguid (1991) in the analysis of the effect of release of residual stresses due to microcracking. Adequacy of this modelling is discussed in Section F. We reformulate the method of analysis of crack interactions presented in

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Mark Kachanov

Section 111for the crack-microcracks configurations. The method allows one to consider arbitrary arrangements of large numbers of cracks by relatively simple means, both in 2-D and 3-D. We concentrate, mainly, on SIFs at the main crack, since they are, typically, higher than SIFs at the microcrack tips (the latter can also be found, if they are of interest).

B. BASICEQUATIONS FOR CRACK-MICROCRACK INTERACTIONS The method of analysis of crack interactions presented in Section 111 is reformulated here for crack-microcrack configurations, by assuming that the microcracks are embedded into the asymptotic crack tip field of the main crack. (Although the method may, in principle, be applied directly to the crack-microcrack configurations by simply taking the main crack to be much larger than the others, such a formulation has certain limitations, see the discussion later). 1. Two-Dimensional Configuration (Semi-lnjiniteCrack and N Microcracks) The stress field in the microcracked zone can be represented as a superposition a(x) = K pJl(X) + K,,a,,(x) +

c a’(x)

(5.1)

where K,, K,, are SIFs at the main crack tip (to be determined); aI= f,(@O(~r)-’~* and uI,= f,I(8)(2ar)-”2 denote modes I and I1 asymptotic crack tip fields and a’ is the ith microcrack-generated stress field (which would have been generated by an isolated ith crack loaded by the tractions t’(t) induced at its site -1’ < t < I’ in a continuous material by the other microcracks and the main crack tip). According to the key simplification of the method, we approximately represent the traction t‘(t) on the ith microcrack as a sum of tractions generated along its line in a continuous material by the main crack tip and the other microcracks, the latter being loaded by uniform average tractions on them:

+ K,IUll(t) + Cai(t)> {Krai(t) + KIIaii(t) + C { < p’>dXt) +

t’(0 = n i * { & ~ l ( t )

n‘ *

(5.2)

where (( p’), (z’)) = (tk) are the average normal and shear tractions on the kth microcrack and d,t$are the “standard” stress fields, normal and shear.

Elastic Solids with Many Cracks and Related Problems

325

The first two terms characterize the impact of the main crack on the ith microcrack and the second is the impact of the other microcracks. Taking the average of (5.2) over the ith microcrack yields N vectorial linear algebraic equations interrelating N average tractions on microcracks and K , , K,, at the main crack tip:

where the transmission A-factors interrelate average tractions on different microcracks and vectors gi = n'-(u,)' and JIi = n ' - ( ~ , , ) characterise ~ the average tractions produced by the modes I and I1 components of the main crack tip field at the site of the ith microcrack. N vectorial equations (5.3)can be further expanded into 2N scalar equations. Two additional scalar equations express the microcracks' impact on the main crack: (5.4a) (5.4b) where KP, K: denote SIFs at the main crack tip in the absence of microcracks, and ui are the stresses generated by microcracks loaded by the uniform average tractions on them. Solving the system of 2N + 2 scalar equations (5.3) and (5.4) yields K , , K,, at the main crack tip and traction averages (tk) on microcracks. If the SIFs at the microcrack tips are of interest, they are found as generated by the (variable) tractions ti(<)obtained by substituting ( t k ) into (5.2). 2. Three-Dimensional Configuration (Rectilinear Crack Front aiid N Penny-Shaped Microcracks) We assume that the microcracks are embedded into the asymptotic crack front field. In 2-D, such a formulation reduces the problem to a system of 2N 2 linear algebraic equations (5.3) and (5.4) interrelating the SIFs K,, K,, at the main crack tip and the traction averages (pi), (zi) on the microcracks. In 3-D, however, such a reduction is not straightforward, since the SIFs are variable along the macrocrack front (due to the interaction with microcracks) and cannot therefore immediately enter a system of linear algebraic equations. One alternative is to revert to the general method of analysis of interacting cracks outlined in Section I11 and simply assume that one of the cracks

+

Mark Kachanov

326

(macrocrack) is much larger than the others. Such a formulation has two limitations. The first one is technical: at the spacings between cracks of the order of lo-’ of the main crack size or smaller, numerical difficulties (related to handling expressions for the crack-generated stresses) arise; the limiting case of a rectilinear main crack front cannot be handled. The second difficulty is more substantial: if the difference in crack sizes is very large, the basic simplification of our method-taking the impact of the macrocrack on the microcrack by assuming a uniform average traction on the macrocrackmay become inadequate. An alternative is to retain modelling of the macrocrack by a rectilinear crack front, but to take its impact on microcracks in a simplified way: to assume that the microcracks are affected by the average (along the front) main crack SIFs (KI, KII,KIII).The errors due to this simplification will be small if (1) the nonuniformities K - (K) of the “primary” SIFs (modes I, 11, I11 SIFs due to the modes I, 11, I11 of applied remote loading, respectively) along the front are not overly large as compared to (K) itself, so that the “double feedback” correction K --+ (K) --+ average tractions on microcracks + K is small and (2) the microcrack field remains statistically homogeneous along the front so that (K) is stable along different intervals of the front (physically, such situation is of primary interest). Results of Laures and Kachanov (1991) show that when the microcrack size constitutes 1/100 of the circular macrocrack, the difference in results produced by both formulations is very small; this justifies, to some extent, the formulation for the rectilinear crack front. Then the average SIFs and the average tractions on microcracks can be interrelated through a system of 3N + 3 linear algebraic equations:

N

(s’)

=

j+i

[AC ( p’)

+ A!:

(z’)

+ A;:

(d)]

Elastic Solids with Many Cracks and Related Problems

+c N

( K J = K?

[s’..
+ W.<7’> + @,,(&]

CO’,,(p’>

+ %(7’>

j= 1

N

+ @L(S’>l

(K,J = K,q

+

(Kill) =

+ j = 1 Cs’.,,(Pi>+ % ( 7 J > + @k(S’>l

j= 1

327

c N

where the @- (and @-)transmissionfactors characterize the average tractions induced by the main crack front at the microcrack sites (and vice versa) so that, for example, @i,, characterizes the impact of the mode I1 main crack tip field on the normal traction on the ith microcrack and Wi, the impact of shear loading on the j t h microcrack on the mode I SIF on the main crack. Note that shear tractions on microcracks are decomposed into the 7 - and scomponents, along the direction of the shear traction generated by the main crack front and the direction normal to it (thus, the s-components reflect the interaction between microcracks only). To find the (variable along the crack front) K , , K,,, K,,, one needs the expression for SIFs along the rectilinear crack front due to a pair of opposite point forces applied at the crack surface. They are given by these formulas (Fabrikant, 1990):

‘ K, = ( z - ~ ) ~ ( c ot)1/zA-3/2 s K,, + XI,,= (K2)p(cos 4;)1’212-3/2{7

+ v(2 - V ) - ’ Z ~ - ~ 1’ ~

(5.6)

where p = p(A, 4;) is the normal point load at the point (A, 5) and 7(A, 4;) denotes a shear point load written in a complex form z = 7, + i ~Integration ~ . of (5.6) along the main crack surface, with distributed tractions p(A, 4;), 7(A, t) produced by the microcrack-generated stress fields

5) = &.(A, 4;)($>

+ 4 4 O ( 7 9 + M,4;)(s’>

(5.7)

will yield the SIFs along the main crack front. To find SIFs along the microcrack edges (if they are of interest), the actual (variable) tractions t i ( M ) on microcracks are found from (5.7) and the SIFs from (3.21) and (3.22) (see Section I11 for proper handling of the integrals for SIFs and other mathematical details). Thus, finding the SIFs is reduced to 0

calculation of the interaction matrix [ A i k ] i.e., , averaging the “standard” field generated by a uniformly loaded ith crack along the kth crack line (surface, in the 3-D configurations);

328 0

0 0

Mark Kachanov

finding tractions averages (t‘) on microcracks from a system of linear algebraic equations-note that the size of this system is moderate (2N + 2 equations in 2-D configurations and 3N + 3 equations in 3-D configurations); finding the (variable) tractions and the SIFs on the main crack; finding the (variable) tractions and the SIFs on microcracks, if they are of interest. 3. Accuracy of the Method

We check the accuracy of the method by comparing the results for SIFs with the solutions available in literature. Such test problems exist in 2-D only. The simplest configuration for which the test solution exists is a collinear arrangement of one microcrack and a semi-infinite main crack (Fig. 30). In this case, the SIF at the main crack tip produced by our method differs from the exact one by 1%, 2% and 7% at A121 = 0.25, 0.20 and 0.10, respectively; A121 denotes the ratio of the spacing between the crack tips to the microcrack length. (We used, as a test, results for two collinear cracks of unequal lengths, with the ratio of the lengths equal to lo3,further increase of the ratio leaves the results almost unchanged, with the appropriate asymptotic expressions for the elliptic integrals in the solution. The results of Rubinstein (1985),who considers the case of a semi-infinite main crack, were not used, since his formulas and graphs were found at some variance with each other.) In the case of two inclined microcracks (“focused” at the main crack tip and symmetric with respect to the main crack line), comparison with the results produced numerically by Hutchinson and Shum shows that the maximal (over all inclination angles) error of our method is 1% and 4% at A121 = 0.5 and 0.25, respectively, increasing to 20% at 6/21 = 0.10 (Kachanov and Montagut, 1989). Comparison with the results of Rubinstein (1986) for a microcrack rotated around the macrocrack tip at the distance A121 = 0.75

OUR METHOD

-

* 60.1

0.3

21

FIG.30. Macrocrack interacting with a collinear microcrack (mode I conditions).

Elastic Solids with Many Cracks and Related Problems

329

shows that, at this spacing, the errors of our method are almost indistinguishable. Dutta, Maiti, and Kakodkar (1991) calculated, using singular finite elements, the SIF in the shielding configuration involving two parallel stacked microcracks; the smallest spacing A121 at which they produced results was 0.25. Their results are in perfect agreement with the ones produced by our method. These examples indicate that, in the 2-D configurations, our method remains accurate (within several percent) at the spacings between crack tips as small as one-quarter of the microcrack length and, in the configurations close to the collinear one, at even smaller spacings; at the spacings on the order of the microcrack length, the errors are indistinguishable in all geometries. In the 3-D crack-microcrack configurations, no test solutions are available, to our knowledge. Test solutions exist, however, for several configurations involving two circular cracks of equal size; comparison with these solutions shows (Kachanov and Laures, 1989) that accuracy of our method in 3-D is much higher than in 2-D. Therefore, the results for crackmicrocrack configurations will be accurate at spacings substantially smaller than in corresponding 2-D configurations; they are expected to retain accuracy at spacings on the order of lo-' of the microcrack size and, in the case of configurations that are close to coplanar arrangements, at even closer spacings. OF A CRACK WITH SOMESIMPLE MICROCRACK C. INTERACTION CONFIGURATIONS

We present here the results for several relatively simple arrangements involving one or several microcracks. Although such configurations do not represent any realistic situations, solutions for them illustrate the influence of various geometrical factors. 1. Macrocrack Interacting with a Collinear Microcrack ( 2 - 0 ) This is an example of an amplifying configuration, in both modes I and I1 loading conditions. Figure 30 shows the results for the main crack SIF and mode I loading conditions. 2. Macrocrack Interacting with Two Parallel Microcracks (2-D) This presents an example of a configuration where the interaction effect depends, even qualitatively, on the geometrical parameters. If the microcracks

330

Mark Kachanov

I

1.04 .

0.0

'

'

- 1

'

:

1.0

'

'

'

-

'

;

2.0

. . .

'

I

3.0

A FIG.31. Macrocrack interacting with two parallel microcracks:the effects of amplification(+) and shielding (-) depend on the position of the microcracks.

are located sufficiently far from the main crack tip (ahead of it), the effect of such interaction is stress amplification (since the main crack "sees" them as one collinear microcrack). If, on the other hand, the microcrack centers are located above and underneath the main crack tip, the impact of interactions is the one of shielding. Figures 31 and 32 show the results for the main crack SIF and mode I loading conditions.

FIG.32. Macrocrack interacting with three parallel microcracks:competition of the shielding and amplificationeffects. Note the short range of the amplifying collinear interaction(similar to the configuration of Fig. 16).

Elastic Solids with Many Cracks and Related Problems

331

9

1.0 0.0

60.0

30.0

90.0

$ FIG.33. Macrocrack interacting with a totated microcrack, mode I loading (spacing between cracks in the undisturbed configuration is one-tenth the microcrack length).

3. Main Crack Interacting with a Rotated Microcrack ( 2 - 0 ) The microcrack center is on a continuation of the main crack line. Results for both modes I and 11 loading conditions are shown in Figures 33 and 34. Note that, as Fig. 33 shows, the impact of the microcrack on the macrocrack is maximal not when the cracks are aligned, but in the configuration with a slightly “disturbed” symmetry; this is a manifestation of the general

0.0

30.0

60.0

$ FIG.34. Same as Fig. 33, mode I1 loading.

90.0

332

Mark Kachanov

1 0.85 0.0

30.0

90.0

60.0

$ FIG.35. Macrocrack interacting with a microcrack located in the “wake” zone, mode I loading (microcrack center is shifted behind and above the macrocrack tip on the distance of 0.8 of the microcrack length). Note the weakness of the interaction effect.

phenomenon (extremal properties of slightly asymmetric arrangements) discussed in Section 1V.C.

4. Microcrack in the “Wake’’ Zone Produces a Very Small Impact

on the

Main Crack (Figs. 35 and 36)

This can be explained by the low level of stresses in the wake zoneintroduction of a microcrack into such a zone produces only a small effect.

L .f.*

0.950.0

60.0

30.0

d

FIG.36. Same as Fig. 35, mode I1 loading.

9

.o

Elastic Solids with Many Cracks and Related Problems

333

5. Three-Dimensional Coplanar Crack- Microcrack Configuration

The amplifying impact of the microcrack shown in Fig. 37 is much weaker than in the similar 2-D configuration (Fig. 30), consistent with the fact that 3D interactions are generally weaker than the 2 - 0 ones (Section IV). Note that in this example the main crack is modelled as a circular one (rather than a rectilinear crack front); the results for both models are very close in this case, consistent with the discussion of Section B. 6. Asymmetric Three-Dimensional Crack- Microcrack Conjiguration

The configuration of Fig. 38 is subjected to mode I loading. Note appearance of the “secondary” modes (K,,, K,,,), as a consequence of asymmetry of the configuration.

D. INTERACTION OF A CRACK WITH LARGEMICROCRACK ARRAYS: TWO-DIMENSIONAL CONFIGURATIONS We solved the interaction problem for a number of sample microcrack arrays representing different realizations of a certain microcrack statistics. SIFs at the main crack tip K,,K,,and at the microcrack tips k,, kll were found.

FIG.37. Mode I stress intensity factors along the edges of a circular macrocrack and a circular microcrack in the coplanar configuration,mode I loading. The ratio of the crack sizes is 20 and closest spacing between the cracks is one-tenth the microcrack diameter.

Mark Kachanov

334

"

051 -20

I

I

00

20

Y/a

-02 -20

00

I0

-2 0

0.0

2.0

yla

Y/a

FIG.38. Mode I loading of the parallel noncoplanar crack-microcrack configuration:stress intensity factors (primary, K,,and secondary, K,,, K,,,)along the main crack edge.

1. Microcrack Arrays

Shape of the microcracking zone was determined from the condition that the maximal tensile stress, as induced by the main crack tip field, reaches certain critical value: a,,, = a*. This criterion was used by several authors (Evans and Fu, 1985; Hutchinson, 1987; Montagut and Kachanov, 1988).The shapes of microcracking zones for modes I, 11, and I11 are shown in Fig. 39. Crack arrays were generated with the help of the random number generator. Microcrack centers were assumed to be randomly located, with an additional restriction that the spacings between cracks were not allowed to be overly small (so that calculations based on our method remained reliable); this was achieved by surrounding each crack by an ellipse having semiaxes 1.11 and 0.371 in the directions collinear and normal to the crack and not allowing the ellipses of different cracks to intersect (the intersections were

Elastic Solids with Many Cracks and Related Problems

335

K*=K n =Krn

FIG. 39. The shapes of the microcracked region for the modes I, 11, 111 and mixed mode ( K I= K,,= KIII)loadings, as determined by the condition u,,, = u-.

avoided by introducing the new cracks successively and discarding any crack whose ellipse intersected the already existing ones). At such spacings between cracks, the maximal error in SIFs is within 5% for all geometries (and is, typically, smaller). Similarly, the distance between the main crack and the ellipses surrounding the microcracks was kept larger than one-quarter the microcrack length. Such avoidance of overly small spacings eliminates the extreme situations of very strong interactions; without this artificial restriction, fluctuation of the interaction effects from one microcrack sample to another (discussed in the next subsection) would have been even greater. Two microcrack orientation statistics were examined: random orientations and the a,,,-statistics (microcracks are normal to the direction of the maximal tensile stress induced at the microcrack center by the main crack). The actual orientational distribution is, probably, in between these two extremes. All the microcracks were assumed to be of the same length, 21 (this assumption was used to limit the number of parameters involved and is not essential for the method of analysis used). The microcrack density p = N12/A ( N is the number of cracks in a representative area A ) was first assumed to be uniform in the microcracked zone and then the effect of variable p , decreasing with the increasing distance from the main crack tip, was examined. Six sample microcrack arrays (consisting of up to 48 microcracks each) were generated for each combination of 0

two orientation statistics, a random one and the (r,,,-statistics; modes I and I1 remote loading; Uniform) microcrack densities p = 0.06,O.12 and 0.23 (in 2-D configurations they can be considered as low, moderate and relatively high).

Mark Kachanov

336

- \

I

-1

\ ”

/ -

-

//7 \

I-

\I

I-

/-

/ /

J-T\’

’

\ -’

,-< I

I‘

\ ’

-

‘I

FIG.40. Some of the sample microcrack arrays for which the interaction problem was solved. Microcrack densities are 0.06,0.12 and 0.23. The shape of the microcracking zone correspondsto the mode I loading. These are random orientation statistics.

Figures 40-43 show some of the sample microcrack arrays for which the interaction problem was solved.

2. Results a. “Short-Range” and “Long-Range” Znteractions The zone of “short-range” interactions, which consists of several microcracks closest to the main crack tip, produces a dominant effect (as compared to the overall combined effect of the “long-range” ones). The interaction effects are highly sensitiue to exact positions of microcracks in this zone. This is further illustrated by the 3-D examples of the next section, where Fig. 45

\-. -- . .FIG.41. Same as Fig. 40: cT,,,-orientation statistics.

-

\ \ '

FIG.42. Same as Fig 40, mode I 1 loading, random orientation statistics.

337

338

Mark Kachanov

FIG.43. Same as Fig. 40, mode I 1 loading, cT,,,-orientation statistics.

will show that removal of all microcracks that are farther away from the main crack front than 1.5 of the microcrack radius produces only a small effect. b. Fluctuation of the Interaction Effectfrom One Microcrack Sample to Another Due to the high sensitivity of the interaction effect to the exact positions of several microcracks closest to the main crack tip, the SIFs at the main crack tip fluctuate significantly from sample to sample, changing from K / K o < 1 (shielding) to K / K o > 1 (amplification). Thus, interaction with microcracks appears to produce no statistically stable effect of either shielding or amplification, at least when the microcrack centers are randomly located. c. “Primary” and “Secondary” Modes Stochastic asymmetries in the microcrack arrays produced noticeable “secondary” modes; i.e., KII(K,)under mode I (11) loading: the ratio K,,/KP of the “secondary” SIF to the “primary” one reached 0.16 for some arrays. Since mode I1 SIF promotes kinking, this effect may be partially responsible for the irregularity of a crack path in brittle microcracking materials. Note that this phenomenon cannot be reproduced by modelling the microcracked zone by a region of “effective” material of reduced stiffness.

Elastic Solids with Many Cracks and Related Problems

339

d. S l F s at the Microcrack Tips These were significantly lower than the ones at the main crack tip for all the microcrack arrays generated. (This conclusion should be viewed with caution, however, since spacings between all cracks were not allowed to be overly small.) e. Mode I1 Remote Loading Here, the interactions tended to be, on average, more amplifying, compared to the mode I conditions. This is in agreement with several simple crack-microcrack problems considered by Kachanov and Montagut (1986, 1989).

f. Nonuniform Microcrack Density Consistent with the dominant role of the short-range interactions, the impact of a nonuniform microcrack density (decreasing with the distance from the main crack) on SIFs at the main crack was found to be small: reduction of the density in the part of the microcrack array farther away from the tip produced relatively small changes (smaller than fluctuations of the interaction effect from one sample to another) and, therefore, can be considered statistically insignificant. g. Impact of the “Wake” Region of Microcracking We examined the hypothesis that microcracking in the wake region (“behind” the main crack tip) produces a substantial shielding effect. In several crack configurations with a frontal microcracked zone, a large number of additional microcracks (up to 75) was gradually added into the wake region. The wake region had length of up to nine microcrack lengths. Introduction of additional microcracks into the wake region produced some shielding in our computer experiments, but it was, typically, smaller than the fluctuations of the interaction effect from one sample microcrack array to another. For example, in one of the configurations, introduction of a wake produced a change in K,/KP from 1.05 to 1.00 (this case is shown in Fig. 44)whereas in another K,/KP changed from 0.77 to 0.75 (the latter example represents a relatively rare occurrence of a significant shielding); as seen from these examples, the additional shielding produced by the wake is relatively weak and dominated by the juctuation of the interaction efect from one realization of the microcrack statistics to another. Similar results were

Mark Kachanov

340

.

-

/I

-

FIG. 44. Gradual introduction of microcracks into the “wake” region. The interaction problem was solved for each arrangement shown.

obtained for the microcrack fields with the a,,,-orientation statistics. It appears, therefore, that the effect of the wake is not statistically significant, at least for the wake lengths considered. The question that remains open is whether a wake of a much larger length produces a substantially stronger effect. We note that stresses in the region adjacent to the (traction-free) macrocrack are quite low, so that introduction of a microcrack into the wake region, particularly at a distance from the main crack tip that is an order of magnitude (or more) larger than the microcrack length, produces a virtually indistinguishable effect. One can expect, therefore, that a further increase of the wake Iength is unlikely to produce a strong effect. h. “Clusters” of Microcracks The effect of a microcrack “cluster” on the main crack tip has been analyzed by placing the microcracks in a circular zone having diameter D of 5.2 microcrack lengths; the cluster was located on the continuation of the main crack line (see Montagut, 1989, for details). The spacing between the main crack tip and the cluster was equal to D;at such spacings, sensitivity to

Elastic Solids with Many Cracks and Related Problems

34 1

the positions of the individual microcracks within the cluster is low. Microcrack orientation statistics was assumed to be random. It was found that the effect of the cluster on the main crack tip can be simulated by one “effective” collinear microcrack; the length of this “effective” microcrack increases with the microcrack density p inside the cluster. At p on the order of 0.32-0.35 (about 30 microcracks in the cluster), the length 2L of the “effective” microcrack approaches D. Computer simultations seem to indicate that, at lower p, L is approximately proportional to D’12.

3. Crack- Microcrack Interactions in an Anisotropic Matrix Interaction of a crack with a field of arbitrarily oriented and located microcracks in an orthotropic matrix was analyzed by Mauge and Kachanov (1990,1993) and Mauge (1993). The anisotropy of the matrix significantly affected the shape of the microcracking zone but otherwise left the basic conclusions (fluctuation of the results, appearance of the secondary modes, etc.) unchanged. E.

LARGEMICROCRACK ARRAYS: THREE-DIMENSIONAL CONFIGURATIONS

INTERACTION OF A CRACK WITH

1. Microcrack Arrays We solved the problem of a rectilinear main crack front interacting with an array of penny-shaped microcracks, for a number of sample microcrack arrays. SIFs along the main crack front were found (SIFs along the microcrack edges were, typically, substantially smaller). Similar to the 2-D case, two microcrack orientation statistics (a random one and the D,,, one) were considered; locations of the microcrack centers were assumed to be random. Crack intersections and overly small spacings between cracks were avoided by surrounding each crack by a cylinder of a height 0.05 of the microcrack diameter and a diameter of 1.01 of the microcrack diameter and not allowing the cylinders to intersect. (This actually allowed spacing between cracks to be as small as lo-’ of the microcrack size or smaller.) Three microcrack densities were assumed: p = 0.15; 0.26 and 0.35, which can be considered, in the 3-D case, as low, moderate and relatively high. For each combination of the orientation statistics, crack density and mode of loading, three different microcrack samples (containing 50 microcracks) were generated and the interaction problem was solved for each. The microcrack density in the zone of microcracking was assumed constant (since, as discussed earlier, the short-range interaction zone plays a dominant role

342

Mark Kachanov

and the decrease of p with increasing distance from the main crack produces only a small effect). 2. Results

The results can be summarized as follows. a. Fluctuation of the Interaction E$ect Along the Crack Front Interaction with a microcrack field produces variable along the main crack front SIFs and intervals of shielding alternate with local peaks of amplification. Since crack propagation initiates at local peaks, their presence enhances crack propagation. This may indicate that interactions with microcracks promote the tendency of a crack front to assume an irregular shape as it propagates. Fig. 45 shows a typical profile of K , along the front under mode I loading. b. “Secondary” Modes Along the Crack Front Similar to the 2-D configurations, stochastic asymmetries in microcrack arrays produce secondary modes and thus seem to promote the out-of-plane crack propagation under mode I loading. Figure 45 shows typical profiles of the secondary modes I1 and I11 along the main crack front under mode I loading. c. Numerical Results For the random orientation statistics and mode I loading, the interaction problem was solved for three microcrack samples for each of the two crack densities, p = 0.15 and 0.35. The maximal (along the front) local peaks of K,/KP were > 1 in all samples; max(K,/KP) over all samples was 1.12. The “secondary” SIFs reached up to 15% of the “primary” ones. For the shear loading conditions, the interaction problem was solved for three microcrack samples of randomly oriented microcracks ( p = 0.26). The local amplifications of KIIand K,,, reached 1.10 and 1.14, respectively. The “secondary” SIFs reached local peaks of 16% of the primary SIFs. The results for p = 0.15 and 0.35 (one microcrack array for each of these densities was examined) were similar. For the a,,,-orientation statistics and mode I loading, the interaction problem was solved for three microcrack samples for each of the densities p = 0.15 and 0.35. The value of K,/KP remained < 1 along the most part of

Elastic Solids with Many Cracks and Related Problems

343

\ -

MODE I MADING

I a0

5

075

K?

0 50 -20

00

20

YJa FIG.45. Three-dimensional interaction of a crack front with an array of 50 penny-shaped microcracks (mode I loading); urn,,-orientation statistics. Typical profile (its “slice”) of a primary SIF K, and “secondary” SlFs K,, and K,,,. The dotted line corresponds to the “truncated” microcrack array (microcracks farther away from the crack front than 1.5 of the microcrack radius are removed). Note that the two lines are quire close; i.e., the short-range interactions are dominant.

the front, barely reaching 1.00-1.02 at the local peaks. Although higher peaks of K,/Kt (corresponding to coplanar configurations and close spacings) can, of course, occur, this limited data seems to indicate that the om,,-microcrack arrays tend to be more shielding than the random arrays. This may be related to the tendency of the om,, microcrack arrays to form relatively small angles with the main crack. For the om,,-orientation statistics and shear loading, the problem was solved for three samples (p = 0.26). The maximal local amplifications of K,, and K,,, were 1.08 and 1.03, respectively.The “secondary” modes (KIII,K, and K,,,K , under modes XI and 111 loading) appeared; their peaks were (0.05,0.15) and (0.06, 0.09) of the primary SIFs, respectively.

344

Mark Kachanou

F. IS MODELLING OF THE MICROCRACKED ZONE BY EFFECTIVE ELASTIC MATERIAL ADEQUATE? As discussed in Sections D and E, the microcracks closest to the main crack front (“short-range” interactions) produce a dominant impact on the main crack SIFs. The short-range interactions are quite sensitive to the individual microcrack positions. Their modelling by a homogeneous elastic material of reduced stiffness would not reflect this sensitivity and, therefore, the inherent statistical instability of the interaction effect. Such a modelling would also miss other important effects, like presence of local peaks of SIFs along the crack front (that makes, in 3-D cases, the overall effect of interactions one of enhancement, rather than shielding) and appearance of “secondary” SIFs that enhance crack kinking. This can be further illustrated by the following example. Laws and Brockenbrough (1987) considered a 2-D interaction of a crack with a hexagonal microcrack array. By modelling the microcracked zone by a weakened elastic material they obtained a noticeable shielding: K,/KP = 0.86. However, a direct solution of the interaction problem for the configuration shown in their article yields the opposite result-a mild amplification: K,/KP = 1.05. (Note that this result would change considerably with the parallel “shift” of the microcrack array with respect to the main crack, whereas the predictions obtained by modelling of the microcracked zone by the effective material would remain the same; see Montagut, 1989,for details). Similar conclusions on inadequacy of modelling of a microcracked zone by an effective elastic material were reached by Curtin and Futamura (1990), who used an entirely different modelling (2-D spring network). Physically, the lack of correlation between the impact of microcracks on SIFs and the fact that microcracking reduces the effective stiffness has a clear explanation: the SIFs are governed by local Jluctuations of the microcrack field geometry whereas the effective moduli are volume auerage quantities that are relatively insensitive to such fluctuations. (See Section VII for a general discussion of this issue).

G.

ON

TOUGHENING BY MICROCRACKING. CONCLUSIONS

As discussed earlier, ifthe microcrack locations are more or less random, the interactions do not produce any statistically stable effect of shielding, due to the fact that the interaction effect is dominated by the short-range interactions. The interaction effect fluctuates, even qualitatively (from shielding to

Elastic Solids with Many Cracks and Related Problems

345

amplification), from one sample of the microcrack statistics to another. Moreover, in the 3-D configurations, the local peaks of SIFs along the main crack front enhance the front advances, making the overall effect of interactions the one of amplijcation. Therefore, elastic interactions with microcracks do not appear to produce any toughening. The analysis reveals some other interesting aspects of the problem. Stochastic asymmetries in the microcrack field produce noticeable “secondary” mode SIFs on the main crack; appearance of the mode I1 SIFs under mode I loading may be partially responsible for crack kinking and irregular crack path. Obviously, these conclusions do not rule out other mechanisms of toughening by microcracking. First, shielding may be produced by elastic interactions with some special microcrack conjigurations (for example, extremely dense microcrack arrays parallel to the main crack, see Chudnovsky and Wu, 1990). We note, also, that the locations of naturally occurring microcracks may not necessarily be random: one may expect that the main crack tip field enhances nucleation of microcracks in its amplification zone and thus creates an “amplification bias” in the microcrack patterns. On the other hand, an opposite “bias” appears to have been observed as well: experimental observations of Han and Suresh (1989) seem to indicate that some (but not all) of the observed microcrack patterns are “biased” toward shielding. Second, toughening by microcracking may be due to mechanisms other than elastic interactions (some of them are mentioned in Section A). Our analysis is an elastostatic one and does not predict the evolution of SIFs as the main crack front propagates. For example, one may argue that local advances of the crack front, enhanced by local peaks of SIFs, will eventually be “trapped” by a shielding local arrangement of microdefects; examination of this hypothesis would require analyses of crack fronts of complex shapes. These problems are beyond the scope of the present work and need further studies.

VI. Effective Elastic Properties of Cracked Solids The theory of effective elastic properties of cracked solids predicts degradation of stiffness, development of anisotropy and changes in wavespeeds caused by microcracking. Therefore, it is of obvious interest for materials science, structural mechanics and geophysics. Most of the approaches to this problem have roots in the effective media

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Mark Kachanov

theories of physics. For example, the approximation of an efectiue matrix (a self-consistent scheme, in the terminology of the mechanics of solids with inhomogeneities),in which a representative inhomogeneity is placed into the effective matrix and its modification-the differential scheme-were first used in the problems of electrostatics, by Maxwell and by Bruggeman in 1935. The method of an efectiue field (Mori-Tanaka’s method being its simplest version), in which a representative inhomogeneity is embedded into the effective field, was first developed in 1940s and 1950s in connection with wave propagation problems (Lax, 1951). At the same time, cracks constitute a distinctly special kind of inhomogeneities: they occupy no volume; stress fields generated by them are quite complex and have strong orientational dependence. As a result, cracked solids have many special features: the choice of crack density parameter is nontrivial; the effective properties are, generally, anisotropic; bounds for the effective moduli generally cannot be established; the approximation of noninteracting cracks has a wider than expected range of applicability. Several approximate schemes have been suggested in literature (and a number of their modifications and combinations can, probably, be added). Their predictions are substantially different. A researcher, trying to use the theory, may well be confused by the choice of several models, yielding different results. Here, we attempt to introduce some clarity into the problem. We start with a detailed review of the approximation of noninteracting cracks, not only because it is the only noncontroversial approximation, but also because our direct computer experiments (as well as the method of effective field and Mori-Tanaka’s method) show that it remains accurate at high crack densities, provided the locations of crack centers are random. We pay particular attention to anisotropy caused by non-randomly oriented cracks. We then discuss various approximate schemes and the possibility of bounding the effective moduli. When locations of crack centers are nonrandom, we suggest an alternative crack density parameter, which is sensitive to mutual positions of cracks.

A. INTRODUCTION 1. Solid with Cracks us. Solid with Inclusions

The problem of effective moduli of cracked solids can formally be regarded as a limiting case of the more general problem for a matrix containing

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347

inclusions: in this limiting case, (a) inclusions shrink to surfaces and (b) their elastic moduli tend to zero. Such an approach leads to some difficulties, however: (1) The results may depend on the order of the mentioned transitions to limit. The proper one first sets the inclusion’s moduli to zero (thus creating a cavity) and then shrinks the cavity to a crack. An attempt to reverse the order leads to difficulty: in the framework of linear elasticity, infinitesimally thin platelets of finite stiffness do not affect the effective moduli, thus becoming “invisible,” and the second transition to limit cannot be made (unless it is combined with the first one and a special constraint is imposed). (2) The parameter of concentration used in mechanics of composite materials-relative volume of inclusions-should be changed, since it is zero for cracks. The commonly used crack density parameter (introduced by Bristow, 1960, and used by subsequent authors, starting with Walsh, 1965) is: 1 p =-

A 1

p =V

1 1(i)2 in 2-D (rectilinear cracks of lengths 21’, A is the representative area) (6.1) P 3in 3-D (circular cracks of radii li, V is the representative volume)

1

Some definitions include a multiplier A in the 2-D case (or 4n/3, in the 3-D case), so that p is the relative area (volume) of circles (spheres) with cracks as diameters. For cracks of iioncircular shapes in 3-D, p was generalized by Budiansky and O’Connell(l976) to 2 1 p =-nV

1(S/P)‘”

(6.1a)

where S and P are the crack area and perimeter. (3) Some approaches of mechanics of composite materials degenerate for cracked solids. Bounding the effective moduli constitutes an example: neither upper nor lower nontrivial bounds (which would apply to any sample of crack statistics of a given density and given orientational distribution) can be established for cracked solids (see the discussion of Section I). Another example is Mori-Tanaka’s method for materials with interacting inclusions: being applied to cracked solids, it yields results corresponding to noninteracting cracks. A direct approach to the problem of effective moduli of cracked solids (rather than the one based on mechanics of two components materials) appears, therefore, more efficient.

Mark Kachanov

348

2. Average Strains and Stresses in a Cracked Solid Since displacements are, generally, discontinuous across crack surfaces S', the strains are singular at S'. Thus, the strain field in a solid with cracks is a sum of regular and singular parts: E(X)

= M:u(x)

+1

(bn i

+ nb)'d(S')

where, in representing the regular part as M :u, the matrix material is assumed to be linear elastic (characterized by a compliance tensor M), and 6(Si)is a delta function concentrated on S' (as a derivative of a unit step, it has the dimension of length - '). A colon denotes contraction over two indices; bn, nb denote dyadic (tensor) products of the displacement discontinuity vector b = u+ - u- (crack opening displacement) and unit normal n to a crack. Vectors b and n are, generally, variable along cracks; their directions are coordinated by defining the + side of S as corresponding to the positive sense of n (then change of sign of n changes the sign of b and the products bn, nb remain invariant). In the following, we assume that the matrix material is elastically homogeneous: M(x) = constant = Mo. Averaging (6.2) over V and using the property of 6(S) that Jvf(x)6(S)dV reduces to the surface integral Jsf(x) dS yields the volume average of strain: E = Mo:a + -

iv

(bn i

+ nb)dS = (Mo + AM):u 5 M : a

(6.3)

[st

where AM is the change in compliance due to cracks and M is the effective compliance. Linear dependence of b' on ij (used in (6.3)) assumes linear elasticity of the matrix and absence of friction along crack faces (if friction is present, then (6.3)is to be rewritten in the incremental form and AM depends not only on 6 but, also, on the direction of d6, see Section D). Volume averages 5 and a can be expressed in terms of quantities defined on the outer boundary r of V; i.e., in terms of experimentally accessible (measurable)quantities. Since, as follows from the divergence theorem, ii for a simply connected region is given by the integral (1/2V) Jr (un + nu) d r , this integral defines E for a volume element of the efective (homogenized)material. Thus, if displacements are prescribed at the boundary of r! then, by definition, introduction of cracks into V does not change ii. At the microstructural level, introduction of cracks produces redistribution of strains: due to the contribution from displacement discontinuities into the unchanged total E, strains in the matrix decrease.

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349

Average stresses are defined in terms of quantities on r as (l/V)JrXTdT, where x is a position vector (counted from the centroidal point) and T is a traction vector. This definition is justified by the fact that, as follows from the divergence theorem, u = (l/V) Jr xT d r , for both a simply connected region and a region with traction-free cracks, provided the body force is constant in V (as noted by Lehner, 1992, the latter requirement can be relaxed). Thus, by definition, introduction of cracks does not change the average stress, if tractions are prescribed on the boundary. This means that, if a certain stress component is locally amplified by a crack (say, has a singularity near the tip), this is compensated for by “unloading” at other points of a solid. If stress is constant (=ao)along r (“homogeneous boundary conditions,” Hashin, 1983), then another application of the divergence theorem yields ao = a. If the RVE constitutes a part of a statistically homogeneous field of cracks and is sufficiently large to be representative, then it can be reasonably hypothesized that substitution of the actual stress on r (generally, fluctuating along r) by its constant average will affect only a “boundary layer” of V (having thickness on the order of the fluctuation wavelength) and will not significantly change u, so that no z 0. If, in addition, the remotely applied om is such that, in the absence of cracks, the stress field would have been homogeneous, then uo can be approximately identified with am(for a more detailed discussion of statistical homogeneity and related issues, see Hashin, 1983, and Beran, 1968). We add only that the identification uo = u = amis exact for noninteracting cracks, when cracks inside the RVE experience no influence of those outside. In the following, we omit the overbar for stresses and strains, assuming E = Eand n = 8 = om. Forpat cracks, n = constant within each crack, and (6.3) takes the form E

= Mo:a

-1 +1 ((b)n + n(b))’S’ 2v ’

(volume V and areas s’are to be changed to area A and lengths 21 in the 2-0 case) where (b’) is b‘ averaged over S’. Thus, contribution of a given crack into the overall strain is proportional to the product (crack area)(b). The unknowns are vectors (b’) as functions of u. Representations of the type of (6.3) or (6.4) have been routinely used since at least the 1970s as a starting point for analysis of cracked solids (see, for example, Varakin and Salganik, 1975). They directly follow from a more general case of arbitrary cavities; as follows from the divergence theorem,

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Mark Kachanov

the cavity’s contribution into the overall strain is an integral over the cavity surface (- 1/2V)

b

(un

+ nu) dS

It reduces to the second term of (6.3) when cavities shrink to cracks.

3. Elastic Potential (Complementary Energy Density) of a Cracked Solid Elastic potential f of the effective material is obtained by contracting aij/2 with taking the latter from (6.4) yields f in terms of “microstructural” quantities defined on S‘: 1

1

1

~(u)=-u:M~~~:u=-u:M +-2V~ : u~i ( n . e . ( b ) ) ’ S i - f 0 ( a ) + A f 2 2

(6.5)

(to be appropriately modified in the 2-D case) where fo(e)is the potential of a matrix without cracks. For an isotropic matrix with Young’s modulus Eo and Poisson’s ratio vo

where, in the 2-D case, E,, changes to E, (= E, for plane stress and Eo/(1 - vg) for plane strain). Expression (6.5) plays a central role in further analysis.

4. COD Tensor

We introduce tensor B that interrelates a vector of uniform traction t applied at the crnck faces and the vector of resulting average COD:

(b) = t . B

(6.7)

The second-rank tensor B can be called a COD tensor. It depends on the crack size and shape, on the elastic properties of the matrix and, in the case of anisotropic matrix, on the orientation of the crack with respect to the anisotropy axes of the matrix. In the case of a body of finite size, it also depends on the body’s geometry. In the case of an isolated crack in an infinite body with stress e at infinity

Elastic Solids with Many Cracks and Related Problems

351

(such that, in the absence of a crack, the stress state is uniform), (6.7) can be rewritten as

(a)

= n.a.B

(6.7a)

In the coordinate system (n, t) where t is tangential to the crack, the diagonal components B,,, B,, characterize the normal (shear) CODs produced by the normal (shear) tractions. The off-diagonal components characterize coupling of the modes (generally present for cracks in finite bodies; for cracks in an injnite body, it is generally present in the case of anisotropic matrix; and in the case of noncircular cracks in an isotropic matrix, between any two inplane directions, unless these two directions are the principal directions of the crack shape). Betti's reciprocity theorem implies that Btn = B,; ie., B is symmetric.

5. COD Tensor of a Crack in an Injnite Isotropic Solid

In the case of an infinite isotropic matrix, normal and shear modes are uncoupled. In 2-D, B is proportional to a unit tensor: B = (nl/Eb)I

(6.8)

reflecting equal compliances of a crack in normal and shear modes. In 3-D, for a circular crack (radius I ) , B = pnn + y(tt + ss), where s and t are any two orthogonal vectors in the crack plane, and B = 161(1 - vg)/3nE0; y = B/(1 - v0/2).Note that B is not proportional to I, since normal and shear compliances of a crack are different. Since tt + ss + nn = I, we can rewrite B in the form

(:)

B = y I--nn

The I-term corresponds to the part of COD that is collinear to the traction n * a;the on-term characterizes the deviation from collinearity. An important observation is that the coefficient of the nn-term is substantially smaller than the one of the I-term, reflecting a relatively small difference in normal and shear compliances of a circular crack (vanishing at v,, = 0). For an elliptical crack, tensor B can be constructed by utilizing Eshelby's results on ellipsoidal inclusions (that were specialized for elliptical cracks by Budiansky and OConnell, 1976). Tensor B has the form B = (nn

+ qss + ctt

(6.10)

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Mark Kachanov

where s and t are unit vectors of the major, 2a, and minor, 2b, ellipse’s u, ( are expressed in terms of elliptic integrals: axes. Coefficients =4(1- v$)b/(3E0E(k)),where E(k) is the complete elliptic integral of the first kind of the argument k = [l - (b/a)2]”2 and 9, [ are obtained from 5 by changing E(k) to expressions Q-’and R - ’ , respectively, where Q and R are given by formula (31) of Budiansky and O’Connell. Using the identity on + ss + tt = I, we transform (6.10) to the form

<

r,

where the first two terms are similar to B of a circular crack; the third term reflects deviation of the crack shape from circular and is responsible for the noncollinearity of the shear traction and the resulting shear COD. B-tensors are particularly useful in the cases of noncircular cracks and cracks in anisotropic matrix.

B. NONINTERACTING CRACKS. CRACK DENSITY TENSOR. ORTHOTROPY 1. General Remarks. Nonequivalence of the Assumptions of Noninteracting Cracks and Small Crack Density In the assumption of noninteracting cracks (in the isotropic matrix material) the effective moduli can be found exactly, for an arbitrary crack orientation statistics, in both 2-D and 3-D. It is the simplest (and the only noncontroversial) approximation to the problem; at the same time, it has a wider than expected range of applicability (Section I). It is often called the approximation of small crack density (in fact, the two names are usually used as synonyms). We refrain, however, from using this term, since these two assumptions are generally not equivalent. Indeed, if locations of crack centers are nonrandom, interactions can be strong (and the discussed approximation inapplicable) at vanishingly small density (see the examples of Section J). On the other hand, in the case of random locations, predictions of the approximation of noninteracting cracks remain accurate at high crack densities (due to cancellation of the competing effects of shielding and amplification, see Section I). In the approximation of noninteracting cracks, each crack is regarded as isolated it is embedded into the a-field and does not experience any influence of other cracks. Then (b) for each crack is expressed, in a simple way, in terms of o*u.Mutual positions of cracks do not matter in this approxi-

Elastic Solids with Many Cracks and Related Problems

353

mation, hence averaging over a crack array is reduced to summation over orientations. Since the change in compliance AM due to cracks is a sum of the isolated cracks' contributions, the compliance is linear in the crack density parameter. Elastic strfnesses, obtained by inversion of compliances, will be functions of the crack density of the form (1 + C p ) - ' . Linearization of this form corresponds to the assumption of small crack density. If, however, this form is left as it is, then, as seen later, the results remain accurate at high crack densities. The problem of effective elastic moduli in the approximation of noninteracting cracks was first solved, for randomly oriented cracks, in both 2-D and 3-D, by Bristow (1960). His calculations were repeated and extended to the case of frictional contact between crack faces by Walsh (1965). Since averaging is reduced simply to integration over orientations, such calculations are easily repeated for an arbitrary (nonrandom) orientational distribution. Such calculations were done by a number of authors. For one or several families of parallel cracks in 3-D, the moduli were explicitly derived by Piau (1980), where the derivation was done in connection with the wave propagation problems (and, from the point of view of finding the effective properties, was not the simplest); for the sine and cosine orientational distributions of penny-shaped cracks, by Zhao et al. (1989). They are implicitly (in the form of elastic potential) given, for arbitrary orientation distributions, by Kachanov (1980). They are also contained, explicitly or implicitly, in papers on self-consistent and differential schemes (see, for example, Hoenig, 1979). The results can be written in the most general form (arbitrary orientational distribution and crack shapes) by using the B-tensor and introducing (6.7a) into (6.5). This yields the elastic potential

Af = (1/2)a:AM:~

(6.12)

where AM = (l/A) = (1/2V)

li(nBn)'

in 2-D

C S'(nBn)'

in 3-D

(6.13)

is an additional compliance due to cracks (AMijklis to be appropriately symmetrized, with respect to i w j , k CI I , ij c,kl). The presentation that follows is based on the concept of the crack density tensor. It leads to results for arbitrary crack orientational distribution in a simple unified way, avoiding averaging over orientations. This tensor

3 54

Mark Kachanou

(introduced by Vakulenko and Kachanov, 1971; Kachanov, 1972 and, in a more complete and corrected form, by Kachanov, 1980a) emerges naturally as a term in the elastic potential. We emphasize that the choice of this tensor as a measure of crack density is dictated by the structure of the elastic potential. 2. Invo-Dimensional Case Vectors (b') and n'*a are collinear:

(b') = (nl'/Eb)ni-a

(6.14)

since "compliances" of a crack are the same in shear and normal modes. This collinearity has important implications for symmetry of the effective properties, as will be seen. Substituting (6.14) into potential (6.5) (or, equivalently, B-tensor (6.7a) into (6.12) and (6.13)), one obtains Af = (n/Eb)((~.(~):a = (n/Eb)oijojkaik

(6.15)

1 a = - C (i2nn)' A i

(6.16)

where

is a second-rank crack density tensor (summation may be substituted by integration over crack orientations? if computationally convenient). Since n - n = 1, the linear invariant t r a = akk is the conventional scalar crack density: (6.17) so that a is a natural censorial generalization of p that accounts for crack orientations. Thus, elastic potential is a function of (I and a:

where Af is a simultaneous invariant of (I and a, quadratic in (I (linear elasticity at fixed a) and linear in a (noninteracting cracks). This invariant structure reflects isotropy of the matrix: if both (I and a undergo the same orthogonal transformation (say, rotation) then the potential is insensitive to any such transformation.

Elastic Solids with Many Cracks and Related Problems

355

Equivalently to (6.15), one can specify the compliance increment due to cracks AM,, = a2Af/aaijaot, as AMij/cI

= (n/Eb)d{ikaj/)

(6.15a)

where the subscript braces denote all the appropriate symmetrizations (with respect to i w j , k t)I, i j c,kl). We emphasize that, for noninteracting cracks in 2-D, these representations in terms of a are rigorous, and they follow from collinearity of vectors (b') and ni * a. The crack density tensor is symmetric (as a sum of symmetric dyads). Therefore, it has a principal representation: a = Plelel

+ p2e2e2

(6.19)

( p , , p2 and e l , e2 are principal values and principal unit vectors of a).

Each term in (6.19) represents a family of parallel cracks. Therefore, any system of cracks iffully equivalent, in its impact on the effective moduli, t o two mutually perpendicular families of parallel cracks. As a consequence, the effective properties are orthotropic (rectangular symmetry) for any orientational distribution of cracks; the orthotropy axes coincide with the principal axes of a. This result, rigorous for noninteracting cracks in 2-D, may not be intuitively obvious (for example, it covers situations of the type of (6.28), Fig. 46). Moreover, the orthotropy is of a simplijied type: 1. Since a is a second-rank tensor with nonnegative eigenvalues, the variation of elastic compliances with direction is described by ellipses (rather than fourth-order curves that may have complex shapes, as in the case of general orthotropy); 2. The number of independent elastic constants is reduced from four (general orthotropy in 2-D) to three, due to the relation between shear and Young's moduli and Poisson's ratios (it follows from (6.15) and (6.19)): w 1 2

= (1

+ Vl2)lEl + (1 + v21)/E2

(6.20)

(Curiously, this relation was suggested in the general theory of elasticity of anisotropic solids by Saint-Venant, simply as an approximation for reducing the number of constants, see Lekhnitsky, 1963); 3. Under uniaxial loading i n any direction, the presence of cracks does not cause any additional lateral strain: v12lE1 (=v*,lE2) = VOlEb

(6.21)

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Mark Kachanov

It is a consequence of a entering Af through only one invariant (a.a):a (in principle, one may construct one more invariant(a :a)tr a - that is quadratic in a and linear in a,however, it does not

enter A& Therefore, Af does not contain the product ~ 1 1 a 2 2This ). implies that the change of Poisson’s ratio due to cracks is the same as the change of Young’s module: v12/vo = E,/E,. This fact implies (in conjunction with (6.20))that the shear modulus can be expressed as l/GlZ

=

1/E1

+ 1/E2 + 2vo/Eb

(6.20a)

Thus, all elastic constants can be expressed in terms of two Young’s moduli El, E, and one matrix constant vo/Eb. The advantage of the representation (6.15)in terms of a is that the effective moduli are readily obtained for arbitrary orientational distribution of cracks without aoeraging over orientations as soon as this distribution is characterized by a. This is illustrated by the examples that follow. a. Isotropic (Random) Orientation Distribution The crack density tensor is isotropic, and, since tr a = p , a = (PI211

(6.22)

where I is a 2-D unit tensor. Inserting (6.22) into (6.15) yields the elastic potential:

from which the effective moduli follow: E’ = Eo(1

+ np)-l;

v = vo(l + q

I - 1

(6.24)

b. Parallel Cracks (Normal to the x1 Axis) In this case, a = pelel and the potential takes the form

(6.25)

Elastic Solids with Many Cracks and Related Problems

357

from which one obtains Young's modulus in the x1 direction and the shear modulus E ; = Eo(1

+ 2 7 ~ ~ ) ~GI, ' ; = Go[l + (27~GO/Eb)p]-'

(6.27)

Young's modulus in any other direction (inclined to cracks) is obtained by expressing a in the inclined coordinate system; variation of compliance with the angle of inclination is shown in Fig. 48 (solid line). c. 'Tivo Families of Parallel Cracks

To illustrate convenience of the crack density tensor, we consider an example of two families of parallel cracks inclined at an angle 30" to each other; one has the density twice as high as the other (Fig.46). The crack density tensor is a = (2p/3)n1n1

+ (p/3)n2n2

(6.28)

where nl, n2 are unit normals to cracks of the first and second families. Finding the eigenvalues of a and substituting the principal representation of a into the elastic potential, we obtain that the principal directions of orthotropy are rotated 9.5" to n1 and that Young's moduli in these directions are Eb/(l + 5.86~)and Eb/(l + 0.42~). In the case of several systems of parallel cracks, a

=

C pknknk

(6.28a)

where Pk are partial crack densities, and introduction of (6.28a) into the elastic potential yields results in an elementary way. 3. Three-Dimensional Case (Circular Cracks) Unlike the 2-D case, (b') is not collinear to n'sa, and the proportionality

FIG.46. Orthotropy axes in Example c.

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Mark Kachanov

relation between (b') and n'.u should be written for the normal and shear components separately (see Section 11):

where /3 = 16(1 - vi)/3n and y = 16(1 - vtH1 - v0/2)-'/37r. The compliances of a crack in normal and shear modes are di$erent, p # y (unless vo = 0), although not by much: y = p/(1 - v0/2). Substituting (6.29) into (6.5) (or, alternatively, substituting B-tensor (6.9) of a circular crack into (6.12), (6.13) yields Af =

8(1 - v;) 3(1 - Vo/2)Eo

vo

1

where (6.16a) is the crack density tensor (3-D equivalent of (6.16)) Unlike the 2-D case, Af is not a function of u and a only, but contains an extra term involving the fourth-rank tensor (1/V) (Pnnnn)'. This term causes deviations from orthotropy. Emergence of this term (and, thus, insufficiency of a)is a consequence of the noncollinearity of vectors (b') and n'.u in 3-D. This term's contribution A M into the effective compliance makes the decrease of Poisson's ratio with increasing crack density slower than the decrease of Young's and shear moduli (moreover, Poisson's ratio does not even tend to zero in the limit); see discussion following formula (6.37). Another feature of A M is that it has an unusual symmetry: since (1/V) (Pnnnn)' is symmetric with respect to all rearrangements of indices, AMYlzz= A M Y z l 2and two similar relations, indices 23 and 31, so that AM" contributes equally into the Poisson's ratio effect and the shear moduli. However, the overall impact of this term is small. In particular, deviations from orthotropy are small, due to the following two factors. First, the extra term has a relatively small multiplier v0/2 (this is a consequence of a relatively small difference between normal and shear compliances of a circular crack). If its relative weight is evaluated by the ratio

c

K = (AMYjkiAMGkl)'i2/(AMijkl AMijkr)'/2

(6.31)

of the Euclidean norms of the compliances AM" and AM' corresponding to this term and to the a-term, then K < vo/,,h (Kachanov, 1980a).

Elastic Solids with Many Cracks and Related Problems

359

Second, only a part of this term causes deviations from orthotropy; a substantial part of AM” has the structure of orthotropy coaxial to a and simply adds to the orthotropic moduli A M . The following examples demonstrate the smallness of errors caused by omitting the extra term. These errors can be further reduced if, instead of simply omitting the extra term, we eliminate it in a different way; namely, if we enforce the normal and shear compliances of a crack to be the same and equal to their average, i.e., by replacing @ and y in (6.29) by (B + y)/2, then Af z Af(a, a) =

8(1 - vi) 1 - v0/4 cr*u:a 3Eo 1 - Vo/2

(6.32)

and the fourth-rank tensor is eliminated from the potential. Thus, characterization of a crack array by the crack density tensor a only (that leads to orthotropy of the effective properties) constitutes a good approximation. The examples that follow (in which the effectivemoduli are found both ways-with the extra term retained and omitted-are compared) illustrate this statement. a. Isotropic (Random) Orientation Distribution Both the crack density tensor a and the fourth-rank tensor (1/V)C(13nnnn)’ are isotropic. Since t r a = p, (6.33)

a = (P/3)I

(I is a 3-D unit tensor). Since tensor (l/V)C(l3nnnn)’ is isotropic, its ijklcomponents have the form C1dijdkl C2(6ik6j, + 6 i l 6 j k ) ; since, in addition to being isotropic, it is symmetric with respect to all rearrangements of indices, C , = C, and the ijkl-components are C(6,6,, + dikdj1 6i,6jk),where C is some constant. Since (l/~‘)C(l’n-nn-n)’ = p so that 6 f i 6 k k 2dikdik ( = 15) = p, the constant C = p/15. Inserting this tensor and (6.33) into (6.30) yields

+

+

+

and the effective moduli readily follow:

G -GO =[l+

16(1 - VoX1 - V0/5)

9(1 - vo/2)

V +

8(1 - vi) 45(1 - v0/2) p ] (6.35)

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Mark Kachanou

Note that ifonly the a-term is retained in (6.30) and the term containing the fourth-rank tensor is omitted, the effective moduli (6.35) change to v

G

E

9(1 - vo/2)

9(1 - v,/2)

(6.36) which are close to the rigorous result (6.35). If the potential (6.32), obtained by replacing the normal and shear compliances /3 and y by their average (fl + y)/2 is used, then the effective moduli -E= [ l + EO

G

-GO =[l+

16(1 - vgX1 - v0/4) 9(1 + vo/2) 16(1 - vo)(l - Vo/4) 9(1 - V O P ) PI

v

;

E

vo = -Eo

(6.37)

are even closer to the rigorous result (6.35). We now examine the impact of the fourth-rank tensor on Poisson’s ratio. In contrast with the 2-D case, Poisson’s ratio decreases slower than Young’s or shear moduli, with the increasing crack density (formulas (6.35)). Moreover, Poisson’s ratio does not even tend to zero in the limit (instead, v/vo approaches (10 - 3v0)-’). These features illustrate the impact of the fourthrank tensor on Poisson’s ratio. However, the difference between E/Eo and v/vo is relatively small; this illustrates smallness of the mentioned effects. These features of the Poisson’s ratio behavior disappear if the fourth-rank tensor is removed from the elastic potential, either by simply omitting the corresponding term or by enforcing equal compliances of cracks in normal and shear modes (formulas (6.36) and (6.37)). b. Parallel Cracks (Normal to the x1 Axis) The crack density tensor u = pelel

(6.38)

and the fourth-rank tensor (1/V)~(13nnnn)’= pelelelel. Thus, =O’

+

8(1 - v;) 3(1 - vo/2)Eo

(6.39)

361

Elastic Solids with Many Cracks and Related Problems

so that

(6.40) If only the a-term is retained in (6.30), then the moduli (6.40) change to lql 3(1 - vo/2)

PI-';

G I , remains unchanged

(6.41)

or, if the potential (6.32) is used,

(6.42) Both (6.41) and (6.42) are close to the exact moduli (6.40). c. More Complex Crack Orientation Statistics To illustrate the orthotropic character of anisotropy in more complex crack orientation statistics, we consider an example (similar to (6.28) in 2-D) of two families of parallel cracks inclined at 30" to each other, one having a density twice as high as the other. The crack density tensor is given by (6.28) and the fourth-rank tensor (1/V)C ( I 3nnnn)' = (2p/3)n'n'n1n1 + (p/3)n2n2n2n2. The principal axes of a are the same as in the 2-D case. Unlike the 2-D case, orthotropy, strictly speaking, does not hold, due to the fourth-rank tensor's contribution. However, the deviationfrom orthotropy is small. Indeed, calculated in the principal axes of a, the effective compliances AM,, (obtained by expressing a and the fourth-rank tensor in the principal axes of u and inserting them into (6.30)) are as follows (normalized to p / E o ; vo = 0.25 is assumed):

AMl,,, = 0.167,

AM22,2 = 2.370, AM3333= 0

AM1122 = -0.019,

AM2233 = 0,

AM1212

= 1.400,

AM2323 = 0,

AM3311 = 0 (orthotropic moduli) =

(6.43)

The rest of the moduli would have been exactly zero in the case of rigorous

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Mark Kachanov

orthotropy (the fourth-rank tensor’s contribution neglected). They are quite small, compared to (6.43):the only nonzero ones are A M , , , , = 0.004,

A M z z l z = -0.004

(nonorthotropic moduli)

(6.44)

Their relative weights, evaluated by the ratio (6.3l ) , is negligible: = i.4x 10-3. Note that, as seen from (6.43),A M , , , , is on the order of lo-’ of A M , , , , and AMZ2,,; i.e., the impact of cracks on the lateral strain is small, compared to the impact on the shear and Young’s moduli. This illustrates the accuracy of representation of an arbitrary crack array by the crack density tensor (and of relations (6.45) following from such representation). 4. Simplijied Character of Orthotropy. Number of Independent Constants As shown earlier, the effectiveelastic properties of 3-D cracked solids are approximately orthotropic. Similar to the 2-D case, the orthotropy is of a simplijied type: 1. Directional variation of the compliances is described by ellipsoids

(rather than surfaces of the fourth order, as in the case of general orthotropy). 2. The number of independent constants is drastically reduced, from nine (general orthotropy) to only four, due to the following simplifications (similar to the ones in 2-D): a. Shear moduli can be expressed in terms of the Young’s moduli and Poisson’s ratios through three equations of the type of (6.20); b. Under uniaxial loading in any direction, the presence of cracks does not cause any additional lateral strain: V12/E1 = v n / E z = V3i/E3 = Vo/Eo

(6.45)

This fact, together with the general symmetry relations for the compliance tensor v i j / E i = v j , / E j , implies that all six Poisson’s ratios can be expressed in terms of the Young’s moduli Ei and the matrix constant vo/Eo. It further implies (in conjunction with (6.20)) that the shear moduli, too, can be expressed in terms of Ei and vo/Eo: 1/Gij = 1/E,

+ 1/Ej + 2vo/Eo

(6.46)

Thus, the entire set of elastic constants can be expressed in terms of three

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363

Young’s moduli Ei and one matrix constant v o / E 0 . These simplifications may have implications for wave propagation in cracked media, since they may allow one to interrelate various wavespeeds in a medium with crack-induced anisotropy.

5. Loss of “Sharpness” of Anisotropy when Parallel Orientations Are Disturbed. Loss of Isotropy due to Disturbances of Orientational Randomness

Some naturally occurring crack systems have preferential orientations, but they are not ideally parallel. We analyze the impact of disturbance of parallel orientations on the effective moduli. In particular, we examine the loss of “sharpness” of anisotropy and a gradual transition to isotropy as the disturbance increases. We consider one system of parallel cracks. The case of several such systems can be analyzed by using the crack density tensor and summing up contributions of individual systems. We restrict our attention to the 2-D case; analysis in 3-D is similar. The most natural modelling of this situation is to assume that the orientational distribution density p ( 4 ) follows the normal (Gaussian) distribution. However, to present the results in the form of elementary functions and in view of the low sensitivity of the results to the exact form of p(+), we assume a more convenient form of ~ ( 4 )We . consider two cases (Fig. 47): a. Case A Distribution p ( 4 ) has a sharp peak at = 0, and there are no cracks with orientations outside a certain interval 141 < 4o < 742. We model this situation by assuming

P(4) = b o y COSY47 if 141 < 40

and P ( 4 ) = 0, if 141 > 40

(6.46)

where the multiplier (1/2)p0y is due to the normalization condition

1:

p(c$)d4 = po (total density)

(6.47)

and parameter y characterizes the “sharpness” of the peak, i.e., the ratio (equal to ny/2) of the maximal density pmax= p(0) to its average ( p ) = po/n.

Mark Kachanou

364

(*Ar‘:2

-7r/2

n/2

-T/2

n/z

FIG.47. Disturbance of parallel orientations of cracks: (A) Distribution p ( 4 ) with a sharp peak; (B) distribution p(4) with a mild maximum.

b. Case B Distribution p ( 4 ) has a mild maximum at 4 = 0 and cracks of all orientations (- n/2,n/2)are present. We model this situation by assuming 1

P(4) = 5 Po ___ sin yn/2 cosy4

(6.48)

where parameter y characterizes,again, the “sharpness” of the peak: the ratio p,,,/(p) = ny/(2sin 742) and y --+ 0 corresponds to a uniform (isotropic) distribution. The crack density tensor is an integral over orientations (6.49)

In Case A, the components of a and Young’s moduli are all= 3 p o [ 1

{El, E d

-=

E,

+ (1 - 4 ~ - ~ ) -cos’ n/b]

1 1 + 2n{a11, az2} 1

- + npo[l *

and aZ2= p o - a,, 1 (cosn/b)/(l - 4y-2)1

(6.50)

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365

In case B, the components of a and Young’s moduli are

For a numerical illustration, consider the case when the total crack density po = 0.2 (as discussed later, the approximation of noninteracting cracks

remains accurate at such densities, provided locations of crack centers are random). For ideally parallel cracks, the ratio E1/E2= 0.44. It changes to 0.48in the case of a sharp peak in the orientational distribution, characterized by the ratio p,,,/(p) = 9.4. In the case of a somewhat less sharp peak, p,,,/(p) = 4.4,the ratio changes rather noticeably to 0.54; in this case, E2/E0 changes from unity for ideally parallel cracks to 0.88. In the case of a mild maximum, p,,,/(p) = 1.16, the ratio E , / E , = 0.92, dropping to 0.86 for a somewhat sharper maximum p,,,/(p) = 1.32; in this case, EJEo changes from 0.61 for an ideally isotropic distribution to 0.66. The anisotropy becomes practically indistinguishable(E,/E2 = 0.97)when the ratio pmax/pmin = 1.24; i.e., it is noticeably different from unity. This shows a low sensitivity of the effective isotropy to mild disturbances of orientational randomness. 6. “Natural” Coordinate System for Eflective Elastic Moduli. Formulation of the Plane Problem for a Cracked Solid

As discussed previously, the effective elastic properties of solids with noninteracting cracks possess an orthotropy coaxial with a (exactly in 2-D and with good accuracy in 3-D). The principal axes of a constitute, therefore, a “natural” coordinate system for calculation of the effective moduli. In this system, the matrix Mijklhas its simplest form (orthotropic or close to it). The results of computer experiments on sample arrays (Section I) indicate that orthotropic symmetry still holds with satisfactory accuracy for interacting cracks, so that this “natural” coordinate frame remains the system of choice for computing M i j k l . This discussion has implications for the plane problem of elasticity for a cracked solid. In the case of an anisotropic solid, the plane problem can be formulated only in the plane of elastic symmetry. This implies that plane problem for a cracked solid can be formulated only in one of the principal planes of the “natural” coordinate system formed by the principal axes of a.

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Mark Kachanov

7 . On the Effect of Dimensionality Comparison of the stiffness reduction due to cracks in 2-D and 3-D (coefficients at p in formulas (6.24)and (6.35),or in formulas (6.27)and (6.40)) shows that, at the same crack density, the reduction is substantially weaker in 3-0. This conclusion is somewhat relative, though, since each of the definitions (6.1) of p can always be made to incorporate an arbitrary multiplier. A somewhat more solid comparison can be based on adding multipliers a and 4 4 3 into the definitions of p in 2-D and 3-D, respectively, making p a relative area (volume) swept by cracks when such cracks are rotated about their centers (diameters). Comparison based on this modified p still shows a substantially weaker sensitivity to cracks in 3-D: for randomly oriented cracks, for example, the coefficient at p in the formula for E/Eo in 3D constitutes only 0.42 of that in 2-D (assuming vo = 0.25). We note, in this connection, that not only the impact of noninteracting cracks is weaker in 3D, but interactions between cracks are also weaker in 3-D (see Section 1V.A).

8. Noncircular Cracks

We consider now elliptical crack shapes and analyze the impact of the shape factor on the overall effective properties. As discussed in the Introduction, the COD tensor for an elliptical crack has the form

B = -q + ' [ I + ( x ?+' 2

-'

l)nn+-(ss-tt) ? ?+'

]

(6.52)

where s and t are unit vectors of ellipse's axes (2a and 2b) and 5, q, C are given by elliptic integrals. An important factor for anisotropy of the overall properties is whether the vector (b) is collinear to n-a. From this point of view, the three terms of (6.52) play different roles. The first term characterizes the part of (b) that is collinear to the traction vector n u. The second term characterizes deviation from collinearity due to the difference between the shear compliance (averaged between the two principal directions of the ellipse) and the normal compliance of a crack. Therefore, the coefficient at the second term is small if (q + [)/2 is close to the normal compliance 5 (as in the case of a circular crack). The third term describes the situation in the crack plane. It characterizes deviation from collinearity of the in-plane component of n * a from the inplane component of (b) and vanishes if the crack is circular.

-

Elastic Solids with Many Cracks and Related Problems

367

Substitution of (6.52) into the general expressions (6.5) and (6.7a) yields the elastic potential as a sum of three terms corresponding to the three terms in (6.52):

+ -n2 0:-1V

xi

(6.53) {ab

n(ss - tt)n}:ts

The third term consists of a sum of the differences nis-u:, where gas,nntare the shear stress components along the s and t directions (of the major and minor ellipses axes). These differences enter the sum with multipliers that depend on the crack sizes and aspect ratios. If the aspect-ratio distribution is uncorrelated with the size and orientation distributions, then the third term vanishes. The first two terms of (6.53) have the same general structure as the potential (6.30) of a solid with circular cracks. They are indeed very close to (6.30); this is seen by introducing equivalent circular cracks, as follows. Guided by the crack density parameter (6.la), we replace the ith crack contribution into (6.53) by the contribution of a circular crack having the same ratio S2/P.The radius 1 of the thus defined equivalent circular crack is expressed in terms of the semiaxes a, b as l3 = nab2/(2E(k)). The elliptic crack and the equivalent circular crack produce exactly the same normal strain; i.e., they have the same product (crack area)(b,). The shear compliance of the equivalent circular crack diyers, however, from the averaged (between two principal directions of the ellipse) shear compliance of the elliptical crack. This difference depends on the aspect ratio a/b of the ellipse, but remains small even at large ratios a/b:it is 0.7%, 2.5% and 3.2% for a / b = 2, 6 and 58, respectively. Therefore, the vector (crack area)(b) is approximately the same for these cracks, in terms of both the direction and the magnitude of this vector. Thus, replacement of an elliptical crack by the equivalent circular crack is adequate with very good accuracy and the potential (6.53) can be replaced by the potential (6.30)of a solid with equivalent circular cracks. Therefore, all the conclusions on orthotropy, descriptions in terms of crack density tensor, etc., hold for a solid with elliptical cracks. This conclusion holds provided the aspect-ratio, size and orientation distributions of elliptical cracks are uncorrelated (so that the third term in (6.53) can be neglected).

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Mark Kachanov

9. Historical Remarks on Crack Density Tensor, Orthotropy and Potentials in Terms of Invariants Crack density tensor and construction of the elastic potential f in terms of simultaneous invariants of u and u were introduced by Vakulenko and Kachanov (1971). The crack density tensor was introduced there in a more general form that covers dislocations as well as cracks and, in the case of cracks, allows one to incorporate information on crack faces’ displacements. For the study of effective elastic properties of a solid with narrow cracks, (6.16), (6.16a) is the appropriate definition; it is dictated by the structure of the elastic potential. The corresponding discussion (with an overview of modifications and applications of the crack density tensor) was given by Kachanov (1980a). Orthotropy of the effective properties was pointed out by Kachanov (1972). Tensors similar to u and construction of the elastic potential (or, equivalently, of the elastic compliance) in terms of invariants were subsequently used by several authors. Oda et a!. (see, for example, 1984) used a “crack tensor” F coinciding with a to within a multiplier 271 (the fourth-rank fabric tensor was also used; however, it was additionally assumed that vectors n - a and (b) are collinear in the 3-D case, although, as discussed earlier, this assumption actually eliminates the fourth-rank tensor’s contribution into the effective moduli. Litewka (see, for example, 1986) considered, primarily, periodic crack arrangements and used a symmetric second rank “damage tensor” D that differsfrom a by carrying information on crack widths (as a consequence, the effectivecompliances may not be fully consistent with the rigorous results for narrow noninteracting cracks, see his formulas (5-6, at z + 0). Krajcinovic (1985) used a similar construction of the potential in terms of invariants, with the difference that uectors, rather than tensors, were used for characterization of cracks (inconsistencies associated with vectorial characterization are discussed in Section VI.B.12). Talreja (1985) applied this construction (with vectors, 1985, changed to tensors in 1987) to the case of cracks in anisotropic matrix (see discussion of Section C). Tensors of the a type were applied by a number of authors to studies of various jiacture processes. The more general version of the crack density tensor that carries information on crack openings (Vakulenko and Kachanov, 1971) was applied by Allen, Harris, and Groves (1987) and Lee, Allen, and Harris (1989) to the description of damage in composites; Dragon and Mroz (1979), Dragon and Chihab (1985), and Chihab and Dragon

Elastic Solids with Many Cracks and Related Problems

369

(1990) used it in a study of damage evolution in rocklike materials and in ductile materials; Talreja (1991) applied it to the study of damage in ceramic composites. Murakami and Ohno (1981) and Murakami (1983) used a “damage tensor” S2, which differs only by a normalizing multiplier from the modification of a used by Kachanov (1972). It is intended to characterize the grain boundary cavitation in creep and is defined in terms of a sum of grain boundary surface elements. (Note that, being normalized to the total area of cavities in a representative volume, S2 does not seem to vanish when damage vanishes.) General discussion of area loss-related tensors was given by Betten (1982). Both Betten and Murakami and Ohno proposed to construct constitutive laws in terms of simultaneous invariants of c and S2, fully similar to the constructions described in this section. We note, as a general comment, that whereas the area loss-related tensors may be appropriate for characterization of creep processes, their use in the problem of elastic properties may lead to inconsistencies (see the discussion of Section VII). For example, it implies that contribution of a given crack into the change of the overall property in 3-D is proportional to its area, rather than to (area)”’. For the elastic properties, tensor (6.16), (6.16a), naturally emerging in the elastic potential, should be used. 10. Applications of Crack Density Tensor t o Other Physical Properties

Tensors of the a type can also be applied to characterization of physical properties other than elastic of cracked solids. These tensors should then be appropriately modified-a multiplier at an individual crack’s dyad nn should be changed from I’ or I’ (as in the case of elastic properties in 2-D or 3-D) to the one that properly reflects the relative contribution of a given crack into the overall property. Analyses of this kind can be done, tor example, forjuidfiltrationthrough a fissured medium and for the electro- and heat conductivity of a medium with cracklike isolators or conductors. Since these physical laws interrelate vectorial quantities (rather than tensors u and E), the tensors that characterize the effective physical property are of the second (rather than fourth) rank. Their specification as functions of a is therefore simpler than specification of the effective elastic moduli. To illustrate the logic of such analyses, we considerfluid filtration through a fissured material following the work of Kachanov, 1975, 1980a (see also a similar work by Oda, 1985;for an earlier analysis of filtration anisotropy due

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Mark Kachanov

to several planar systems of fissures, which is lengthier and does not use tensorial representations, see Romm and Pozinenko, 1963). Darcy’s law for the effective anisotropic permeability, as formulated by Ferrandon (1948), is V =

-p-’K.Vp

(6.54)

where v is the filtration rate, p is the viscosity coefficient and Vp is the externally applied pressure gradient. Symmetric second-rank tensor K characterizes the anisotropy of filtration. Assuming that the “background” permeability in the absence of fissures is isotropic (K = kl), we aim at specifying the change in permeability K - kI due to fissures as a function of the a-type tensor. We note that in rock mechanics it is usually assumed that permeability due to several families of discontinuities is a simple superposition of the individual permeabilities (the underlying assumption-that energy losses at intersections can be neglected-is, typically, adequate, unless discontinuities of one family terminate at the bedding planes of the other family, resulting, possibly, in noticeable energy losses due to sharp changes in flow directions; see Wittke, 1990, for a detailed discussion). It implies that characterization of discontinuities by the a-type tensor (insensitive to mutual positions of fissures) is adequate. Tensor u should, however, be modified, to account for the fact that, according to the hydrodynamic laws, the contribution of a given fissure into v is proportional to its area and to its opening cubed. Thus, a should be changed to a = (1/V) C (Wnn)’ (6.55) i

The dependence of K - kI on a is an isotropicfunction (if both Vp and the array of fissures undergo any orthogonal transformation, say, rotation, then v undergoes the same transformation). Cayley-Hamilton’s theorem then implies that K - kI is a polynomial quadratic in a, with coefficientsfunctions of invariants of a. Since, as remarked previously, v is a sum of the individual fissures’ contributions, the polynomial should be linearized in a (similarly to linearity of the elastic compliance in a for noninteracting cracks). We further note that a family of parallel fissures does not affect permeability in the direction normal to them. These considerations allow one to fully determine K-kI as a function of a:

K - kI = C[(tra)I - a] where C is a constant of a hydrodynamic nature.

(6.56)

Elastic Solids with Many Cracks and Related Problems

371

Similar analysis can be applied to electric (or heat) conductivity of a medium with cracklike conducting or isolating surfaces, by specifying the corresponding tensor in Ohm’s (or Fourier’s) law as a function of the (appropriately modified) crack density tensor (Kachanov, 1976, 1980a). Note that dyads of the nn-type, formally similar to those comprising a, have been used in the (unrelated to cracks) problem of contacr stresses in a granular material by Satake, 1978 (see also review of Mehrabadi, Nemat-Nasser, and Oda, 1982). 11. Noncoaxiality of Direrent Physical Properties of Cracked Solids Tensors characterizing anisotropy of various effective physical properties-elastic compliance, fluid filtration, electric conductivity, heat conduction-can all, in the approximation of noninteracting cracks, be specified as functions of symmetric second-rank crack density tensors. One may be tempted, therefore, to use the measured anisotropy of one property (say, electric conductivity) to judge anisotropy of another property (say, elastic moduli or fluid permeability); such correlations are sometimes used in geophysics. However, such correlations cannot generally be established, since diflerent modijications of the crack density tensor should be used for characterization of different physical properties. For example, the impact of fissures on fluid permeability is highly sensitive to the fissures’ openings (as reflected in the definition (6.55)of the crack density tensor) whereas the linear elastic moduli are unaffected by them (as reflected in the definition (6.16)).Principal axes of these modifications of a and, therefore, the principal axes of diflerent physical properties have diyerent orientations. 12. Remarks on Characterization of Cracks by Vectors Several authors (Talreja, 1985; Krajcinovic, 1985; Costin, 1985) used vectors (rather than second-rank tensors) to characterize crack arrays; for a given crack, the vector is taken in the direction of a unit normal n, and its length is determined by the crack size. Generally, only even rank tensors may be used as such parameters (see, for example, discussion of Onat and Leckie, 1988). More specifically, the following inconsistencies resulting from the vectorial characterization can be pointed out. 1. It is not clear how to introduce the overall (average)vectorial parameter characterizing the entire crack array. In particular, it is not clear what

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Mark Kachanov

such a parameter would be in the simplest case of randomly oriented cracks (for a second-rank tensor, no such difficulty arises-it is proportional to a unit tensor I). 2. This difficulty is usually avoided by “discretization”,i.e., by retaining the entire set of vectorial parameters ni for each crack (or each family of parallel cracks) and using them as parameters in the elastic potential alongside the stress tensor u (or strain tensor 8). Then, f is constructed in terms of simultaneous invariants of vectors n’ and u (similarly to constructing f in terms of invariants of u and a).However, one still runs into difficulties: a. The number of invariants that should be allowed into f is very large, among them are all the combinations (n’ * u nj)(nk u * 0’) and each entering f with a coefficient to be determined (for (tr uxo’* u * d), example, for three systems of parallel cracks there would be 42 coefficients). b. Formation of simultaneous invariants requires that u, as a secondrank tensor, contracts twice with vectors n’. Thus, there are no terms linear in n’. Therefore, the simplest case-the approximation of noninteractiny cracks (when compliance is linear in crack density)cannot be recovered.

-

-

13. Concluding Remarks The underlying reason for adequacy of the crack density tensor as a parameter of a crack field is collinearity of vectors n*uand (b) (exact in 2-D and approximate in 3D). This implies orthotropy. Therefore, the crack density tensor becomes inadequate to the extent this collinearity is violated. Several physically important situations of this kind are discussed in the next three sections.

c. NONINTERACTING CRACKS IN AN ANISOTROPICMATRIX 1. On the COD Tensor of a Crack in an Anisotropic Solid

Modes I and I1 are coupled: normal or shear traction on a crack produces both normal and shear CODs. This is reflected in the nondiagonality of the COD tensor B B,, = B,, # 0. Also, B = B(n): compliance of a crack depends on its orientation with respect to the anisotropy axes of the matrix. In the case of arbitrary anisotropy of the matrix, B-tensors can be found

Elastic Solids with Many Cracks and Related Problems

313

only numerically. In the case of a 2 - 0 orthotropic matrix, the problem can be solved in a closed form. Referring to Mauge (1993) and Mauge and Kachanov (1992) for analysis of the general case, we consider here one important special case when the effective moduli can be found in a relatively simple form.

2. 2 - 0 Orthotropic Matrix with Cracks Parallel to the Axes of Orthotrory In this case, the normal and shear modes are uncoupled. Using the solution of Ang and Williams (1961), we find, after some algebra, the average normal and shear CODs for a crack normal to the x2 axis:

- 2vy2 + 2(Ey/E!)'/' (b,) =

[{$-

(EyE($'/2a22

= B!,;)a,,

(6.57)

2 4 , -t 2(Ey/E!)"2 }"'/Ey]a12

= B$!)a,,

G12

where B!,:), BI:) are components of the COD tensor (superscript 2 refers to the crack normal to the x2 axis); tensor B(2)is diagonal (B!,? = 0) and is given by the formula

(6.58)

For a crack normal to the x1 axis, tensor B") is obtained from B") by interchanging indices 1 and 2. Introducing tensors B(') and B(2)into (6.13) we obtain the compliance AM due to two families of cracks normal to x1 and x2 (crack densities are p1 and p2, respectively): AM = p,e,B")e,

+ p2e2B'2)e2

(6.59)

(to be appropriately symmetrized) from which all the moduli follow; for example,

E? is obtained from E! by interchanging indices 1 and 2 El

E2

(6.60)

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Mark Kachanov

In the case of one system of parallel cracks, these formuli recover the ones of Gottesman et al. (1980) (which contain a misprint in the expression for the shear modulus). These formulas may serve as a convenient starting point for calculations of the self-consistent and diferential schemes, by changing the matrix’ moduli to the effective ones in the expression for the B-tensor. Such calculations were done, in a somewhat different way, by Gottesman et al. (1980) (self-consistent scheme) and Hashin (1988) (differential scheme). The influence of various elastic constants of the orthotropic matrix on the compliance change due to cracks (aligned with the orthotropy axes of the matrix) was analyzed in detail (with crack interactions taken into account) by Mauge (1990) and Mauge and Kachanov (1990). We now consider the “asymmetry” of the stirness reduction eflect. The impact of cracks on stiffness reduction in the direction normal to them i, stronger (or weaker), compared to the case of the isotropic matrix, if the matrix material is stifer (or sofer) in this direction. This effect is “asymmetric’’: the difference with the case of the isotropic matrix is larger in the case of cracks normal to the stifer direction. As an example, we consider values relevant for glass fiber reinforced plastics: EY/Eg = 4.1; EY/2GY2 = 5; v21 = 0.068; vY2 = 0.277. For parallel cracks normal to the ”softer” direction, we obtain EJE: = (1 + 5.77p2)-’, a small change compared to E/Eo = (1 + 2 4 - l for the isotropic matrix with parallel cracks. For cracks normal to the “stiffer” direction, the difference in the case of the isotropic matrix is much more pronounced: Ei/EY = (1 11.5p1)-’. Thus, the anisotropic matrix is more “sensitiue” (in the sense of stiffnessloss) to cracks normal to the stiffer direction. A somewhat related conclusion has been reached by Mauge (1990) and Mauge and Kachanov (1990, 1992) for interacting cracks in an orthotropic matrix: if cracks are normal to the stiffer (softer) direction, then interactions are enhanced (weakened) compared to the case of an isotropic matrix. Note that, although the overall anisotropy in the considered case is orthotropic, the increment of elastic compliance due to cracks AM cannot be expressed in terms of the crack density tensor a-it depends on tensors B(’) and B”) containing information on matrix moduli.

+

Elastic Solids with Many Cracks and Related Problems

375

3. On Formulations in Terms of Invariants

For cracks arbitrarily oriented in an anisotropic matrix, B-tensors and the effective moduli can be found only numerically. As an alternative, one can take a “phenomenological”approach and assume that, similar to the case of the isotropic matrix, the potential f is a function of a and a, but they enter f through terms that are invariant only with respect to those orthogonal transjormations that belong to the group of elastic symmetry of the matrix. This approach is by no means rigorous, since there is no justification for excluding from the analysis the following factors (the only reason for disregarding them is that otherwise the analysis becomes intractable). 1. The fourth-rank tensor (discussed in Section B), whose exclusion in the case of anisotropic matrix is difficult to justify because the difference in normal and shear compliances of a crack-the main reason for emergence of such a tensor in the potential-may be significant in the case of anisotropic matrix; 2. B-tensors, containing information on the matrix moduli.

If this approach is taken, then the group of the effective elastic symmetry is an intersection of the groups of symmetry of the matrix and of a (the latter being the group of symmetry of an ellipsoid); for example, a 3-D orthotropic matrix with one family of parallel cracks arbitrarily inclined to the orthotropy axes will have no elements of elastic symmetry (and will require a full set of 21 elastic constants). The expressions for f will then be a sum of a large number of simultaneous invariants of a and (x (with respect to a subgroup of the orthogonal group), each invariant entering with a coefficient to be determined (with the hope that information on the matrix moduli that should, in the proper way, enter f through the B-tensors, can instead be entered through these coefficients-an additional assumption of unclear validity). Such an approach was briefly outlined, as a possibility, by Kachanov (1980a); it was fully developed by Talreja (1987) who wrote expressions for f in several cases of the matrix’ symmetry (in the earlier paper, Talreja, 1985, vectors were used for characterization of crack arrays; inconsistencies associated with vectorial characterization were discussed in Section B). This approach leads to emergence of a large number of coefficients at invariants that have to be found experimentally. Since writing f in the form f (a,a) cannot be rigorously justified in the case of anisotropic matrix, these coefficients are not material constants and may simply play the role of

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Mark Kachanov

adjustable parameters (although Talreja’s data indicate their constancy in some experiments). D. NONINTERACTING CRACKS CONSTRAINED AGAINSTTHE OPENING (BUT ALLOWEDTO SLIDE)

This case is relevant for compressive conditions. The difference in the effective properties between this case and the case of freely opening cracks accounts for the differences in compliance under compressive and tensile conditions. Since the deviation from collinearity of the vectors n - a and (b) is substantial in this case ((b) has only tangential components), the crack density tensor u becomes inadequate and orthotropy does not hold. The situation may be further complicated by friction. We assume here that no secondary (“wing”) cracks form. The first quantitative study of a solid with frictionally sliding cracks under compression was done, probably, by Walsh (1965) who found the effective Young’s and bulk moduli. Stress-induced anisotropy, path dependence of deformation and formation of a vertex on a loading surface were analyzed in detail by Kachanov (1980b, 1982). Self-consistentapproximation was applied to the same problem by Horii and Nemat-Nasser (1983); however, as follows from the results of Section I, the self-consistent scheme may actually be less accurate than the approximation of noninteracting cracks. 1. Sliding Without Friction (“Lubricated” Cracks) In this case the behavior is linear elastic. The potential can be found by introducing terms (b) (tangential to cracks) into (6.5). In both 2-D and 3-D (circular cracks) cases, (b) is proportional to the shear traction n u - n * u nn with the proportionality coefficient d / E 0 in 2D and yl/E, in 3-D (see (6.14) and (6.29)).The potential takes the forms

-

Af = (n/E,){(u.a):u - a:(1/A)~(12nnnn)’:a}

in 2-D

Af = (yn/E,){(u~a):u- a:(1/V)~(13nnnn)’:a} in 3-D

(6.61) (6.62)

This form is similar to (6.30):crack density tensor u becomes insufficient and the fourth-rank tensor (l/A) Z ( P nnnn)’ emerges as a term in the potential. However, in contrast with (6.30), a small multiplier v,/2 at this term is absent; therefore, the contribution of this term into the overall compliance can no longer be neglected. Another difference with the case of freely opening cracks is that

Elastic Solids with Many Cracks and Related Problems

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the fourth-rank tensor appears in both 2-D and 3-D. Therefore, orthotropy is significantly violated, in both 2-D and 3-D. The case of elliptical cracks can be analyzed the same way as for freely opening cracks. The two main effects of the constraint are

1. It drastically reduces strains produced by cracks. In the 3-D case of randomly oriented cracks, the constraint reduces the uniaxial compliance due to cracks by the factor of 0.4/(1- 3v0/10). 2. In this case of nonrandom crack orientations, the reduction of strain is even more pronounced. Also, the constraint changes the direction in which the compliance is maximal; i.e., it rotates the anisotropy axes. This is a consequence of the tensor (1/A)Z(I3nnnn)i becoming important. The 2-D case of parallel cracks provides an example (Fig. 48).In the case of freely opening cracks the compliance is maximal in the direction normal to cracks, whereas for constrained cracks the strain response due to cracks is zero in this case, since shear displacements of crack faces (the only source of inelastic strains) are absent. Note that the maximal (over

e FIG.48. Uniaxial compliance (additional, due to cracks) of a 2-D solid with parallel cracks, as a function of direction of loading (forming angle 4 with a normal to cracks), normalized to npa/E,. Dashed and solid lines indicate constrained and unconstrained cracks. Imposition of the constraint shifts the direction of maximal compliance by 45" and sharply reduces strains. This illustrates the difference between compliances of a cracked body in compression and tension.

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Mark Kachanov

all directions) compliance is reduced almost four times when the constraint is imposed. We note that these results can be obtained by using the COD tensor, changed from (6.8) to

B = (d/Eo)(I- nn)

(6.63)

in the 2-D case; from (6.9) to

B = ?(I

- nn)

(6.64)

in the 3-D case of circular cracks, and from (6.10) to B =~

+ [tt

S S

(6.65)

for elliptical cracks.

2. Sliding with Friction If friction is present, vectors (b’) are not unique functions of stress, so that potential does not exist (the tensor of incremental compliance loses symmetry: AMijkl# AMklij).Deformation is loading path dependent, and stressinduced anisotropy emerges; a vertex develops on the loading surface; unloading starts with a “deadband” (stress interval in which no backslidings occur). These issues were investigated by Kachanov (1980b, 1982); here, we briefly review the findings. The “driving force” that produces a shear COD is the shear traction reduced by the frictional resistance. The simplest model for the latter is the Coulomb’s law. Thus, the driving force on a crack is T + po, where T and on are the shear and normal tractions induced on a crack (a, is negative in compression) and p is the friction coefficient;the driving force depends on the crack orientation with respect to loading. The loading path dependence is obvious from the observation that application of shear traction T (while holding on = 0) followed by application of compressive 0, produces a nonzero shear COD, whereas reversing the sequence produces no displacement, if a,, is sufficiently high. Because of the loading path dependence, stress-strain relations have to be formulated in the incremental form (similar to the equations of metal plasticity). However, in contrast with plasticity, the range of loading paths for which deformation is path independent (“fully active” loadings-all cracks that

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379

started to slide, continue to do so, as loading proceeds) is quite wide. For example, in the case of axisymmetric compression u = -q(e,e,

+ e2e2)- pe3e3

where p > 0 and q > 0 are the axial and lateral pressures, with a superimposed stress increment du

=

-dq(e,e,

+ e2e2)- dpe3e3

the range of dp, dq that provides fully active loading is shown in Fig. 49. This range is quite wide: at p = 0.6, for example, the angle ONA differs from n by less than 18". Note the formation of a vertex on the loading surface (in qualitative terms, the development of a vertex in a solid with frictionally sliding cracks was discussed by Rudnicky and Rice, 1975, where a phenomenological model was suggested). The vertex becomes more pronounced as loading proceeds. The strength of this effect depends on friction coefficient, increasing with p and disappearing at p = 0.

q FIG.49. Range of path independence (cone CE) and formation of a vertex on the loading surface in axisymmetrical compression; NA' is parallel to the initial loading surface O A of the most favorably oriented crack. M N shows the loading path (axial compression at constant lateral stress).

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Mark Kachanov

Stress-induced anisotropy develops as loading proceeds, since the strain increment produced by an incremental loading d a superimposed on a current state u depends on orientation of da with respect to a: it is maximal if du is in the direction of u (maximal increase of driving forces z + pnn on the cracks activated at a). It is smaller for directions moderately deviating from a (but still falling in the range of fully active loadings) and is even smaller (or zero) for da forming large angles with u, since such da may “lock” the previously activated cracks. Table I1 shows gradual development of stress-induced anisotropy in the axisymmetric case, as the ratio p / q increases. Note a gradually increasing difference between A M , , , , and AM333, and that AM,,,, #Ah!t331, (indicating that, as expected for path-dependent deformation, the potential does not exist). Although the inelastic strains produced by frictional slidings are, typically, relatively small (compared to the strains of the matrix), they may produce a distinguishable increase of the overall Poisson’s ratio.

E. NONINTERACTING CRACKS FILLED WITH

COMPRESSIBLE

FLUID

1. Basic Equations. Impact of Fluid on Efective Compliance

The impact of fluid on elastic interactions between cracks was analyzed in Section 1V.F. Here, we consider a linear elastic solid with fluid-filled, cracklike cavities in the context of effective elastic properties.

TABLE I1 DEVELOPMENT OF STRESS-INDUCED

AMSOTROPY IN THE AXlSYMMETRICAL LOADING, AS THE RATIO p / 4 OF

~ E INCREASES S (It is assumed that p = 0.6, so that frictional slidings start at p / q = 3.12; compliances are normalized to 8p(l - v;)/[3(2 - vo)Eo] and vo = 0.25 is assumed.)

THE AX~ALAND LATERALS

PI4

M,,,, M3333 M33,1 M1133

3.5

5.0

10

0.190 0.150 -0.241 -0.075

0.340 0.220 -0.382 -0.110

0.458 0.238 -0.439 -0.119

Elastic Solids with Many Cracks and Related Problems

38 1

The collinearity of vectors n - aand (b) is significantly violated, since the presence of fluid reduces the normal compliance of a cracklike cavity, whereas the shear compliance is unaffected. Therefore, orthotropy of the efective properties is noticeably violated. Similar conclusions were reached, on somewhat ditferent grounds, by Sayers (1988), who observed that the elastic anisotropy (as inferred from wave velocities) is reasonably well described by ellipsoids in dry rocks, but deviates substantially from such shapes in puid-saturated rocks. We consider here cracklike cavities filled with compressible fluid, in the approximation when stress interactions between cavities are neglected. Our analysis is somewhat similar to the one of Budiansky and OConnell (1976) but appears to be simpler; it is more general in that it is not restricted to randomly oriented cracks but applies to arbitrary orientational distributions, also it describes dependence of fluid pressures on cavities’ orientation (pressure “polarization”). The analysis of Budiansky and O’Connell differs from ours in that it is done in the framework of the self-consistent approximation, which appears to substantially overestimate the effective compliance (see the discussions of Sections G and H). We assume the “undrained approximation; i.e., that the total mass of fluid in each cavity remains constant (if fluid diffusion across crack faces takes place, this approximation corresponds to a “short-time’’ response). For simplicity of calculation, we also assume that fluid-filled cavities have shapes of relatively thin “platelets.” We first consider the case of cavities circular in plane. The representative cavity has radius 1 and, in the absence of applied stresses, has average opening (b,), average aspect ratio lo = ( b o ) / l and volume d3lO. When stresses are applied, the cavity changes its volume, producing the change of fluid pressure Aq; the latter counteracts the applied traction, reducing the normal COD. Thus, fluid reduces the impact of cracks on the effective compliance, compared to dry cracks. This effect is somewhat similar to imposition of the constraint against opening, but is milder (since the fluid is compressible). Since the cavity is thin, its volume change is mainly due to changes in (b,) ( I remains approximately constant). Thus, the relative change of cavity’s volume AV/V, = ( A b n ) / ( b o ) .Since the fluid mass within a cavity is constant (“undrained” conditions), the change of fluid density q is related to the volume change: qoVo = qY or ArthO

=

-AV/V, = - ( A b ” X b o >

(6.66)

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Mark Kachanoo

The corresponding change of fluid pressure is given by the constitutive equation for a compressible fluid, which, in the linearized formulation (small density changes), has the form

Adlo =

-K&

(6.67)

where K is the compressibility of a fluid (generally, a function of q and temperature, treated as a constant in the considered linearized approximation); in conjunction with (6.66), this equation relates Aq to the change of opening (Ab,). On the other hand, (Ab,) is related to the overall normal traction on a cavity ( n * a * n+ Aq) by a “cavity compliance” relation: (Ab,) = /31/Eo(n.a-n + Aq)

(6.68)

where the compliance of a (thin) cavity is taken to be approximately the same as the one of a circular crack of the same diameter: /3 = 1q1 - v@/3a. These equations yield normal CODs and changes of fluid pressures induced on cracks of different orientations by the applied stress 0: (6.69)

Aq= -

1

1

+ / 3 - l ~ E , l , n-cr’n

(6.70)

Thus, the sensitivity of fluid pressure in a given cavity t o the applied stress is determined by a dimensionless constant

6 = p-lKEOro

(6.71)

This parameter, the key constant of the problem, is similar to the one used by Budiansky and OConnell. It characterizes coupling between stresses andfluid pressures and determines the impact of fluid on the effective compliance. Physically, (6.68) means that the applied compressive stress is counteracted by two factors: “cavity’s stiffness” and the fluid pressure. Parameter 6 determines relative shares of these two factors. In the limit of a highly compressible fluid (K + 00, “air”), change of the fluid pressure in cavities caused by applied stresses is zero and the eflective compliance is the same as in the case of “dry” cracks. In the opposite limit K + 0 (incompressible fluid), Aq = - n u * n and compliance is the same as in the case of cracks constrained against opening (Section D). The same is true if K

-

Elastic Solids with Many Cracks and Related Problems

383

co

is finite but the cavities are infinitesimally thin, + 0, indicating that coupling between stresses and fZuid pressures is stronger for thinner cracks. In general, the compliance is intermediate between that of a medium with dry cracks and that with cracks constrained against opening. As an example that may be relevant for fluid-saturated rocks, we consider the case of IC x 0.5 x MPa-' (water) and Eo x 6 x lo4 MPa (granite). Then, for the cavity aspect ratios co < 0.006 the impact of fluid on the effective compliance is so strong that the compliance differs by less than 10% from that of a medium with cracks constrained against opening. The impact of fluid becomes small (compliance differs from that of a dry medium by less than 10%)only for very wide cavities, at lo > 0.5-0.6 (note that the calculation of the cavity's volume change used above then becomes inaccurate). Thus, in the entire practically interesting range of lo, the effect of stress-fluid pressure coupling is strong and significantly affects the effective compliance. The elastic potential is obtained by introducing the normal CODs from (6.69) and the shear CODs from the expression for the dry cracks into the general expression (6.5). Thus, for the arbitrary orientational distribution of cracks,

(6.72) At 6 + 00, the expression (6.30) for dry cracks is recovered; at 6 -+ 0, the expression (6.62) for cracks constrained against opening is recovered. Since the coefficient of the term containing the fourth-rank tensor is, generally, not small (compared to that at the a-term), the deviationsfrom orthotropy can be signijcant. Effective compliances follow from (6.72). For example, in the case of randomly oriented cracks,

where p is the scalar crack density. Figure 50 shows Young's modulus as a function of crack density for three values of 6. Results for any other orientational distribution of cracks readily follow

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Mark Kachanov

0.0 0.0

2.0

4.0

6.0

P FIG.50. Young’s modulus of a solid with randomly oriented fluid-filled cracks as a function of crack density, at various values of KEOCO.Note a gradual transition from the “dry” cracks curve ( K E ~ C= ~co) to the curve for cracks constrained against opening ( K E J ~= 0).

from (6.72), by inserting the corresponding crack density tensor a and the fourth-rank tensor. For example, in the case of parallel cracks (normal to the x 1 axis) one obtains

(6.74)

The shear modulus is the same as in the case of dry cracks (see (6.40)), in accordance with the fact that fluid does not resist shear displacements of crack faces. Note that the preceding results can be obtained by using the tensor of a circular crack, changed from (6.9) for a dry crack to B = y I---yo 2

(

,.,..) 6

(6.75)

and that these results can be generalized to elliptical cracks by changing the B-tensor given by (6.1 1) to B=

2

[I+ (-

25

6 -1

tl+r 1 + 6

Elastic Solids with Many Cracks and Related Problems

385

In the case of parallel cracks with disturbed orientations (Section B.5), the sensitivity of the effective moduli to the disturbance will be higher than for dry cracks, since the shear mode contributions that appear in the disturbed configuration will not be inhibited by the fluid.

2. Polarization of Fluid Pressure In addition to the impact of fluid on the effective compliance, result (6.70) describes ”pressure polarization”: fluid pressure in a given cavity depends on the cavity of orientation n is expressed as Aq = n - Q * n .As seen from (6.70), cavities of different orientations, fluid pressures will be different in different cavities. It has been suggested (Rice, 1978) that a second-rank “pressure polarization tensor” Q can possibly be introduced, so that a fluid pressure change in the cavity of orientation n is expressed as Aq = n Q n. As seen from (6.70), such a tensor can indeed be introduced, provided all the cavities have the same aspect ratio c,-condition that may be too restrictive; if it is satisfied, then Q = -(1 + 6)-’a. Note that Q = -u in the limit of K E , ~ + , 0. 0

-

3. On Drained and Undrained Conditions The preceding analysis is relevant for the undrained conditions. If fluid diffuses across the cavities’ faces, fluid pressures in different cavities gradually equalize and pressure polarization disappears. In the “long-time’’ limit (fully drained response), the effective compliance becomes the same as that of the dry medium. Thus, in the process of Jluid diffusion, the effective compliance changesfrom that found above to that of a dry medium.

F. SUMMARY ON NONINTERACTING CRACKS

For noninteracting cracks in the isotropic matrix, the results are exact for any orientational distribution of cracks, both in 2-D and 3-D, and are free of controversy. They depend on the density and orientations of cracks but are independent of the mutual positions of cracks. As discussed in Sections H and I, this approximation has a wider than expected range of applicability, due to cancellation of the competing effects of stress shielding and amplification in arrays of interacting cracks. In the 2-D case, the second-rank crack density tensor a provides a fully

386

Mark Kachanov

adequate characterization of a crack array. We emphasize that a, as a parameter of crack density, is not introduced arbitrarily, but is dictated by the structure of the elastic potential. In the 3-D case, a fourth-rank tensor should be used, in addition to a. However, its impact on the effective moduli is small, so that the characterization by a only is a good approximation. The linear invariant tr a coincides with the conventional scalar crack density p, so that a is a tensorial generalization of p accounting for crack orientation. We note that the assumptions of noninteracting cracks and small crack density are not equivalent: for non-randomly located cracks, interactions may be strong and the approximation of noninteracting cracks inapplicable at vanishingly small density p (see, for example, Fig. 54 in Section K); on the other hand, for randomly located cracks, the approximation of noninteracting cracks remains accurate at high densities (Section I). Since a is symmetric and enters the potential through a simultaneous invariant with u, the effective moduli always possess orthotropy coaxial with the principal axes of a (this result is exact in 2-D and approximate in 3-D). Moreover, the orthotropy is of a simplified type-it is characterized by only four (rather than nine) independent constants. This gives rise to the concept of a “natural” coordinate system-principal axes of a-in which the matrix of effective moduli has an orthotropic form in 2-D and close to such a form in 3-D. (For interacting cracks, as discussed in Section I, orthotropic symmetry still holds with good accuracy, so that the “natural” coordinate frame remains the system of choice). The adequacy of a as a sole parameter of the crack field and the orthotropy of the effective properties are consequences of the collinearity of vectors (b) and n. a; i.e., on equal (or approximately equal) compliances of cracks in the normal and shear modes. If this collinearity is violated (cracks in anisotropic matrix, cracks constrained against the opening and fluid-filled cracks), the crack density tensor becomes inadequate and anisotropy of the effective elastic properties is more complex.

G. IMPACT OF INTERACTIONS ON THE EFFECTIVE MODULI: GENERAL CONSIDERATIONS For interacting cracks, the problem becomes much more complex. In principle, it requires solving the interaction problem for each realization of the crack statistics and subsequent ensemble averaging, which constitutes

Elastic Solids with Many Cracks and Related Problems

387

averaging over the (a) orientations, (b) positions and (c) sizes of cracks, Since these are interdependent, this presents a nontrivial (particularly in 3-D) problem related to geometrical probabilities. The difficulty of these steps gave rise to a number of approximate schemes (see the discussion of Section H). The predictions of these schemes are substantially different. A researcher trying to use the theory may be confused by the choice of several models, each yielding different results. The question arises: Which of them is most accurate? There is no definite answer to this question, unless the statistics of crack centers (mutual positions of cracks) is specified. Indeed, if the nonrandom location of crack centers is allowed, then crack arrangements of arbitrarily large density p that produce an infinitesimal impact on the moduli can be constructed, as well as configurations of infinitesimal density p that reduce the moduli to zero (see the examples of Section J). Therefore, if the statistics of crack centers is not specified, any approximate scheme is realizable: a crack arrangement that fits any prediction can be found. (A doubly periodic parallel crack array is an example: at any given crack density, the effective stiffness can be varied from E , to zero by changing the ratio of the spacing between cracks in the collinear and stacked directions. Similar examples can be constructed for randomly oriented but nonrandomly located cracks, see Section J). A more meaningful formulation is this: Which model is most accurate, provided mutual positions of cracks (statistics of crack centers) are random? The first basic question that arises in this connection is: Do the interactions increase or reduce the overall stiffness (compared to the stiffness calculated with interactions being neglected)? The question can be reformulated as follows: Which of the two competing modes of interaction-stress shielding or stress amplijication (resulting in stiffening or softening effects, correspondingly)-dominates in the crack array? The answer depends on the geometries of the shielding and amplification zones near cracks. As an example, consider parallel cracks under tension. Some insight into the mechanics of shielding and amplification can be gained by examining the structure of the stress field oyyassociated with one isolated crack, Fig. 1 (although such considerations are by no means rigorous since the field is distorted by the presence of other cracks). This field consists of small and intense amplification zones (near crack tips) and more “diffused shielding zones. (Note that such a structure is a consequence of the fact that the volume average of oYyis not affected by the presence of the crack if tractions are prescribed, see Section A. Since singularities of tensile stress at the tips

Mark Kachanov

provide a large contribution into the average, the zone where ayy is compressive and has no singularity has to be larger.) As a consequence, the (amplifying)collinear interactions become noticeable only at small spacings between cracks, whereas the (shielding) stacked interactions of parallel cracks have a longer range. (This explains the mechanics of interactions in a doubly periodic array of parallel cracks: the amplification effect is dominant only if ligaments between collinear cracks are substantially smaller than the spacings between stacked cracks; otherwise, the shielding effect dominates and interactions increase the effective stiffness; see the solutions for doubly periodic arrays, Filshtinsky, 1974.) Consider now the case of main interest, when locations of crack centers are random. We recall the general observation that, if tractions ae prescribed at the boundary, then introduction of cracks does not change the average stress in the solid (see Section A). Therefore, one may expect that the competing effects of shielding and amplification are balanced and cancel each other; i.e., that the randomness of crack centers ensures the absence of “bias” toward either amplifying or shielding configurations. If this is indeed so, then the approximation of noninteracting cracks remains accurate at high crack densities, in spite of strong interactions. As discussed later, for at least two orientational statistics-parallel and randomly oriented cracks-these expectations are confirmed, by 1. Computer experiments (Section 1)-solution of the interaction problem for a number of sample arrays of interacting cracks; 2. Calculations of the method of effective field, which takes the mutual positions of cracks into account, and by its simplest version-MoriTanaka’s method.

We note that the outcome of the competition between shielding and amplifying effects is sensitive to imposition of various geometrical constraints that violate randomness of crack locations. One such constraint is the prohibition for the cracks to be overly close to each other. Such a constraint (although in a mild form, minimal allowed spacings were quite small) was imposed, for computational accuracy, on our computer experiments; in the case of parallel cracks, it produced a slight bias toward shielding, resulting in the stiffness being slightly higher than in the approximation of noninteracting cracks. Another example of sensitivity to constraint is the experimental data of Vavakin and Salganik (1975) that showed the effective stiffness to be noticeably lower than in the approximation of noninteracting cracks (the authors interpreted it as a confirmation of the differential scheme). A more

Elastic Solids with Many Cracks and Related Problems

389

careful analysis of their arrays indicates, however, that crack locations were not random-rather, their statistics were close to those in which crack centers are prohibited from entering the circles described around other cracks. Calculations for these particular statistics, done by the method of effective field (Kanaun, 1980, 1983), show that the observed data are fully explained by the constraint; i.e., this constraint produces some bias against shielding arrangements (probably, by eliminating closely spaced stacked cracks-configurations of strong shielding). We emphasize that the accuracy of the approximation of noninteracting cracks at high crack densities reflects the fact that cracks constitute a distinctly special kind of inhomogeneities. As a consequence, some of the approximate schemes used for inclusions and cavities may yield the wrong results when applied to cracks; their attempts to improve the approximation of noninteracting cracks do not necessarily succeed (see Section H). We note, in this connection, that placing a representative crack into an “effective matrix” of reduced stiffness-the basic idea behind the methods of effective matrix (self-consistent, differential)-ignores the stiffening impact of the shielding mode of interactions; thus, it distorts the actual mechanics of interactions. Such schemes predict that interactions always produce a softening effect; i.e., that stiffness, at a given crack density, is always lower than in the approximation of noninteracting cracks (see the discussion of Section H).

H. APPROXIMATE SCHEMES 1. 7jpes of Schemes

Following the common approaches of the continuum physics, most of the approximate schemes reduce the analysis to one isolated crack, placed into some sort of “effective” environment. The effective environment can be defined in two different ways: as an effective matrix or an effective jield. Correspondingly, the schemes can be divided into two groups. The methods of an effectioe matrix place a representative crack into the matrix with effective moduli. Since the crack is treated as isolated, its contribution into the overall compliance is readily found. In the most frequently used scheme, known as a self-consistent one, the entire crack array is placed into the effective matrix in one step, and its impact on the overall moduli is found by summation (done by averaging over orientations) of the individual crack contributions; it is then required that the resulting moduli

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Mark Kachanov

coincide with the effective ones (the self-consistency condition). In the modification known as a differential scheme, the process of placing the crack array into the effective matrix is done in infinitesimal increments, and the reference matrix is recalculated at each step. In another modification, known as a generalized self-consistent scheme, a “cushion” of undamaged material is placed in between the crack and the effective matrix. One can, probably, add various modifications and combinations of these schemes. For example, a differential version of the generalized self-consistent scheme can be constructed in a straightforward way. A “hybrid” of the selfconsistent and the differential schemes, which introduces a crack array into the effective matrix in two steps rather than one (as in the self-consistent scheme) or infinitely many steps (as in the differential scheme), was proposed by Cai and Horii (1992). The method of an effective j e l d places a representative crack into the undamaged matrix, but subjects it to the effective stressjeld (which does not have to be the same for all cracks). The method appears to be more sound from the physical point of view, since it reflects, in an approximate way, the actual mechanics of interactions and has been demonstrated to be more powerful than the methods of effective matrix (for example, it can take statistics of crack centers into account, and the interactions are not predicted to always produce a softening impact). The simplest version, in which the effective field is homogeneous and equal to its volume average, is known as Mori-Tanaka’s method. Other results and approaches exist, which do not reduce the analysis to one isolated crack. They include constructions of a term second order in crack density, a model for an array of parallel cracks of extremely high density, bounding the effective moduli. We also mention that an exact solution is available for a doubly periodic array of parallel cracks with an arbitrary shift ofrows with respect to each other, see Filshtinsky (1974); this solution covers rectangular and “diamond” arrangements as special cases (the special case of a rectangular array was also considered by Delameter et of., 1975, 1977). Zimmerman (1985) made an interesting observation that, as p increases, the relation between different moduli (say, between the shear and Young’s moduli E and G) is almost independent of the scheme used, so that it is difficult to verify a certain scheme by experimentally measuring the E-G curve. A brief review of these schemes and approaches follows.

Elastic Solids with Many Cracks and Related Problems

391

2. Methods of an Effective Matrix These methods model the impact of crack interactions on a given crack by placing the crack into the matrix of reduced stiffness. This hypothesis leads to certain drawbacks, as follows. 1. Crack interactions are predicted to always reduce the effective stiffness, compared to that calculated with the interactions neglected. Thus, the stiffening impact of the shielding interactions (which may fully cancel the softening impact of the amplifying ones) is ignored. This distorts the actual mechanics of crack interactions (see Section G). 2. Since a representative crack is inserted into the effective matrix, the type (and orientation) of the effective anisotropy should be specijied a priori. This leads to difficulties in the case of an arbitrary orientational distribution of cracks. First, the type of the overall anisotropy may not be obvious in cases more complex than randomly oriented or parallel cracks. Second, even if such an a priori judgment on anisotropy can be made, the actual realization of the scheme would require the solution for a single crack arbitrarily oriented in an anisotropic medium-such solutions can, generally, be produced only in numerical form. 3. The schemes are insensitive to mutual positions of cracks, a factor that becomes increasingly important as crack density increases. This seems to limit the schemes to the case of random locations of crack centers. Whether their results are accurate in this case is discussed in Section I. Curves for the effective moduli corresponding to various modifications of the method of an effective matrix and to various orientational distributions of cracks were plotted and compared by many authors; see, for example Kemeny and Cook (1986), Hashin (1988), Sayers and Kachanov (1991). a. Selfconsistent Scheme (SCS) This approach was first used, probably, by Maxwell, in connection with the electrostatics of an inhomogeneous medium. In the mechanics of inhomogeneous materials, this method was used by Hershey and Dahlgren (1954), in connection with effective properties of polycrystals and then in the works of Kroner (1958), Hill (1965b) and Budiansky (1965). For a material with cracks, this scheme was developed by Budiansky and

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Mark Kachanov

O’Connell (1976) for random crack orientations and applied by Hoenig (1979) to crack orientations that are either parallel or have cylindrical symmetry and by Horii and Nemat-Nasser (1983) to frictionally sliding cracks. It was extended to 2 - 0 orthotropic matrices with cracks parallel to the orthotropy axes by Gottesman et al. (1980) and reformulated in a somewhat different form, with particular attention paid to crack shape, by Laws and Brockenbrough (1987). Attiogbe and Darwin (1987) considered, using a numerical procedure (not entirely clear to the present author) for a crack arbitrarily oriented in a transversely isotropic material, the case of the overall transversal isotropy, in which cracks have preferential orientations and all orientations are present. For the purpose of illustration, we review here only the case of random crack orientations. Probably, the simplest way to derive the SCS results is to recall the general expression (6.5) for the elastic potential of a medium with cracks. Vectors (b) depend on the elastic constants. According to the basic idea of SCS, these constants are to be taken as the effective ones. In the 2-0 case, changing E , in (6.15) to the effective modulus E’, one obtains

(instead of (6.23) for noninteracting cracks). Identifying this expression with the potential (6.6), where E,, v, are changed to the egectiue E‘, v, one obtains two algebraic equations for two effective constants. They yield

E = EX1 - np);

v = v,(l

-

np)

(6.78)

At small values of p, these formulas asymptotically coincide with the ones for noninteracting cracks, linearized with respect to p . At larger crack densities, they predict a much “softer” response. At crack density p = l/a the moduli become zeros (“cut-off point). In the 3 - 0 case, changing E,, v, to the effective E, v in (6.34)and identifying thus modified potential with (6.6), where E,, v, are changed to the effective E, v, yields two simultaneous algebraic equations for E(p) and v(p), to be solved numerically. Effective Young’s modulus drops almost linearly with increasing p, to a “cutoff point at p = 9/16.

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b. Comments on SCS 1. The predicted softening effect of interactions is quite strong (substantially stronger than in other approximate schemes), resulting in a “cut-off point for the moduli in the case of random orientations. Even for parallel cracks (for which there is no “cutoff) the moduli rapidly drop to negligible values as p increases: in 3-D, the Young’s modulus drops to about 0.1E, at p = 0.3 (Hoenig, 1979). As discussed in Sections G and I, the actual impact of interactions on the overall stiffness may be quite different. 2. Whether prediction of a “cut-off (at p = l/n in the 2-D case and at p = 9/16 in 3-D) is an advantage of the scheme (since it may be interpreted as the overall loss of integrity at high crack densities) or a disadvantage has been a subject of some discussion (Bruner, 1976; O’Connell and Budiansky, 1976). In our opinion, the scheme that reduces analysis to a single crack (albeit inserted into the effective medium) cannot be expected to predict the loss of integrity, a phenomenon caused by crack intersections. The cut-off point is simply a consequence of the structure of potential (6.77) and seems to have no interpretation compatible with the assumptions of the scheme. Moreover, the cut-off predictions do not seem consistent: if the “loss of integrity” interpretation is accepted, the cut-off cannot be expected in the case of parallel cracks, as indeed shown by Hoenig; on the other hand, for the cylindrical orientation distribution (crack normals lie in parallel planes) the cut-off should be expected, but Hoenig’s calculations do not predict it. 3. Budiansky and OConnell (1976) suggested, as a possibility, that the actual effective stiffness may become very small near the predicted cut-of point. Computer experiments on 2-D arrays (Section I) show, however, that, at p = l/n, Young’s modulus still retains about 40% of E , (see Fig. 53).

c. Formulation of Simplified SCS in Terms of Crack Density Tensor As discussed in Section VI.B.3, the fourth-rank tensor (l/V) X (13nnnn)’in

the potential (6.30) plays a relatively minor role, compared to the a-term, and its neglect leads to relatively small errors (which can be further reduced in formulation (6.32)). Therefore, if one wishes to use the SCS, it can be

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formulated in a simplified way, based on the potential (6.30) with the aforementioned term omitted (or, for a somewhat improved accuracy, based on the potential (6.3.2)).In the case of randomly oriented cracks, this leads to explicit (rather than numerically solved) expressions for the effective moduli E(p), v(p). The results are qualitatively similar to those of the main version (the moduli have the same cut-off point at p = 9/16); quantitatively, the results are very close for E ( p ) and exhibit some variation for v(p). Application of the crack density tensor to the case of non-randomly oriented cracks (anisotropic effective properties) streamlines the calculations of SCS and bypasses the essential difficulty of making an a priori judgment on the type of the effective anisotropy, as well as the necessity to have a solution for a crack arbitrarily oriented in an anisotropic body. Indeed, using the abased potential implies that the effective properties are orthotropic, coaxial with a (as indicated by computer experiments of Section I, this assumption remains valid for interacting cracks). Then, since characterization of a crack array by a means a substitution of the actual crack array by three (two, in the 2-D case) mutually orthogonal families of cracks, the change in the elastic potential due to cracks Af is written by placing a representativecrack into the effective orthotropic matrix, a major simplification being that the crack is normal to one of the orthotropy axes (such solutions exist in closed form in the 2-D case, Ang and Williams, 1961, and in 3-D, Shield, 1951, and Chen, 1966). Finally, the sum f Af is equated to the potential of the effective orthotropic matrix. An even simpler (and less rigorous) technique of formulating the SCS (and other schemes) in the case of nonrandom orientations is suggested in subsection f.

+

d. Dierential Scheme (DS) In this scheme (see Vavakin and Salganik, 1975; McLaughlin, 1977; Hashin, 1988) the analysis is done incrementally: crack density is increased in small steps dp, and the effective matrix moduli are recalculated at each step. The procedure results in differential equations for the effectiveconstants as functions of p (with initial conditions stating that M = Mo at p = 0).In the case of random orientations, there are two equations, for E(p) and v(p), which are coupled in the 3-D case and uncoupled in 2-D. We consider the 2-D case as a simple illustration. For random crack orientations, changing Eb in (6.24) to the “current” E

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and p, to dp and linearizing with respect to (small) dp, results in the differential equation for E' = E'(p): dE'/dp = - n p ,

with initial condition

E'(0)= Eb

(6.79)

which yields: E' = Eoe-"P

(and, similarly, v = voe-"P)

(6.80)

Unlike SCS, there is no "cut-off point at which the stiffness vanishes. For parallel cracks, proceeding similarly to the previous case (using (6.27) as a starting point), we obtain the Young's modulus in the direction normal to cracks: (6.81)

In the case of parallel cracks the predicted stiffness drops much faster with increasing p than in the case of random orientations. At small p, this prediction is correct, since parallel cracks reduce the stiffness more efficiently, but at larger p it seems physically unreasonable, since parallel cracks experience increasing mutual shielding as p increases. e. Comments on DS Unlike the SCS, the DS does not predict a "cut-off point, and thus avoids the problem of its interpretation. On the other hand, the results of DS are not path independent: they may depend on the order of adding cracks of different orientations. This drawback was noted by several authors; we add that, probably, the simplest example of path dependence is provided by two families of parallel cracks forming an acute angle with each other; cracks are widely spaced and the approximation of noninteracting cracks applies. Then the effective properties are rigorously orthotropic (see Section B). If, however, DS is applied and cracks of one family are introduced first, the new reference matrix becomes transversely isotropic; when cracks of the second family are added (at an acute angle to the plane of isotropy), the material becomes nonorthotropic-a wrong prediction. Note that the problem of path dependence surfaces in a simple situation of a 2-D array of low density. A possible remedy for the problem of path dependence is the imposition of the constraint that cracks of different orientations are represented in each crack density increment dp in the same proportion as in the final configuration. Since the DS assumes an imaginary process of gradual addition of cracks, the necessity of placing a restriction on this process seems, however, to

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be a certain disadvantage. Note, also, the conceptual problem that cracks added earlier and cracks added later are placed into different environments (see OConnell and Budiansky, 1976). Similar to SCS, the DS can be reformulated in terms of the crack density tensor. If one wishes to use this scheme, this may simplify calculations in the case of arbitrary orientational distribution of cracks.

f. An Elementary Techniquefor Extension of SCS and DS (and, Possibly, Other Schemes) to Arbitrary Orientations Statistics The aforementioned schemes are difficult to apply to an arbitrary orientational distribution of cracks (particularly in 3-D), since this would require knowledge of a solution for a single crack arbitrarily oriented in an anisotropic solid (available only in numerical form). Sayers and Kachanov (1991) suggested a simple technique for bypassing this difficulty (and eliminating path dependence in DS) by using, as an input, the available results for randomly oriented and parallel cracks and tensorially transforming them to the arbitrary orientational distribution, through the crack density tensor a. In addition to avoiding the mentioned difficulty, this technique is in agreement with orthotropy of cracked solids. The technique automatically transfers some of the functional dependencies of the effective moduli on p from one orientation distribution into another. Such a transfer feature may be seen as a drawback of the scheme; on the other hand, it may be used to correct the undesirable features of the approximate models. Consider, for an illustration, the 2-D case. Recalling the expression (6.15) for the elastic potential Af of a solid with noninteracting cracks, we modify it by assuming that the coefficient at the simultaneous invariant ( a * a ) : ais not n/Eo, but some function of crack density: Af

= g(p)(a.a):a

(6.82)

where g(p) is to be determined from the known results for either randomly oriented or parallel cracks. We then apply this expression to the case of arbitrary orientation statistics. As an example, we consider DS,for which the Young's modulus for randomly oriented cracks E = EOe-'P is used as an input. This implies that Af = (nenP/E0)(aa) :a

(6.83)

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Applying, as a test, potential (6.83) to the case of parallel cracks (a = pelel) we obtain that Young’s modulus in the direction normal to cracks is E/Eo = (1

+ 2zp enp)-

(6.84)

as compared to the actual prediction of DS for parallel cracks (6.85)

The difference between predictions (6.84) and (6.85) (disappearing in the limit p + 0) is moderate: at p = 0.3, it is 0.17 versus 0.15; at p = 0.4, it is 0.10 versus 0.08. At larger densities, the ratio of these two values increases, but this is unimportant, since E becomes very small. Moreover, it is not clear which prediction is actually better, since at large p cracks experience increased mutual shielding and (6.85) may underestimate stiffness (as indeed indicated by the computer experiments of Section I); in this sense, the “transfer” feature turns out to be an advantage-it seems to improve the scheme. Results of DS for any other orientational distribution are obtained by simply introducing the corresponding a into the potential (6.83). In 3-D, the technique is similar and becomes fully identical to that for the 2-D case in a simplified version where the fourth-rank tensor’s contribution is neglected ((6.32), or (6.30) with the second term omitted). The version just presented is somewhat simpler than that of Sayers and Kachanov (1991), due to the fact that the term (a:a)t r a does not enter the potential (it would produce an undesirable effect on Poisson’s ratios, see the comment after formula (6.21); in the work of Sayers and Kachanov the coefficient at this term is actually very small and the results are close to the ones presented here). Being applied to SCS, this technique has the following feature: if the results for randomly oriented cracks are used as an input, then the “cut-off point is transferred to any other orientational distribution; if, on the other hand, the results for parallel cracks are used as an input, then the “cutoff point is eliminated for any orientational distribution. This “transfer” feature may be interpreted as a disadvantage; on the other hand, since the “cut-off’ point itself may be viewed as a disadvantage, the feature may be used for its elimination, by utilizing the results for parallel cracks as an input. g. A Generalized (“Three Phase”) Self-consistent Scheme This scheme was developed by Christensen and Lo (1979) for composite materials. Being applied to a 2-D cracked solid (Aboudi and Benveniste,

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1987), it assumes that the crack is, first, inserted into a circular inclusion of compliance Mo of the undamaged matrix and then this cracked inclusion is placed into the material with eflective compliance M. Thus, a “cushion” (stiffer than the effective matrix) is placed between a crack and the effective matrix. Such modelling is motivated by the fact that the immediate vicinity of a crack is stiffer than the homogenized effective material. Predictably, this scheme produces effective moduli that are stiffer than the ones of SCS; they are quite close to the ones of DS. One of the difficulties encountered in the framework of this model is that the avoidance of overlapping of the circular inclusions containing cracks limits the highest crack density that can be considered (about p = 0.3); it also interferes with the assumption of randomly located cracks. We note that calculations of this model would be difficult in the 3-D case. h. Other Modifcations of the Method of an Effective Matrix One can, probably, add various modifications or combinations of these schemes. For example, a differentialversion of the generalized self-consistent scheme can be constructed; the effective stiffness predicted by such a scheme will be higher than in the generalized self-consisent scheme. A “hybrid of the self-consistent and the differential schemes, which introduces a crack array into the effective matrix in two steps rather than one (as in SCS) or infinitely many (as in DS), was proposed by Cai and Horii (1992); the results are, predictably, in between those of the self-consistent and the differential schemes. 3. Method of an Eflective Field and the Method of Mori-Tanaka

The method of an eflectiuejeld (MEF) was first used, probably, in the wave propagation problems (Lax, 1951). As far as the effective properties of media with various inhomogeneities are concerned, the method was developed and applied to a number of diverse microstructures by Kanaun and Levin. (For references, see Levin, 1976, and Kanaun, 1980, 1983, where a detailed presentation and further references can be found, and their upcoming book on MEF.) The method places a representative inhomogeneity into an effective stress Jield, which, generally, does not coincide with the remotely applied one (this difference accounts for the interaction effect). The condition of selfconsistency is written for this effective field.

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The method possesses substantial advantages, compared to the methods of effective matrix. It takes into account the structure of the stress fields associated with inhomogeneitiesand, thus, incorporates the actual mechanics of interactions. For example, the shielding (stiffening)mode of interactions is not ignored: in contrast with the methods of an effective matrix, MEF does not predict that interactions always reduce effective stiffness. An important feature of MEF is that it takes the mutual positions of defects into account. Being applied to two test configurations-doubly periodic arrangements of parallel cracks-it distinguishes between the effective moduli of the rectangular and diamond arrangements of the same density and reproduces the exact solutions for these two cases very closely. An important result obtained by this method for the cracked medium is that, in the case of random locations of crack centers, the effective moduli coincide with the moduli given by the approximation of noninteracting cracks, at least, for two orientational distributions-randomly oriented cracks and parallel cracks (Kanaun, 1980, 1983, 1992). This result is in full agreement with the results of our computer experiments. It shows that randomness of mutual positions of cracks ensures the absence of “bias” toward either shielding or amplifying configurations. Another interesting result produced by MEF is that imposition of the constraint prohibiting centers of cracks to enter the circles drawn around neighboring cracks lowers noticeably the effective stiffness (i.e., creates a “bias” against shielding arrangements). This result fully explains the experimental data of Vavakin and Salganik (who interpreted their data as a confirmation of the differential scheme). The method allows various refinements, by letting the effective fields to be different for different inhomogeneities, and even allows each defect to be embedded into an inhomogeneous field. The simplest version of MEF, in which the effective stress field is assumed to be the same for all inhomogeneities and equal to the volume average over the matrix is known as MoriTanaka’s method (1973). Mori-Tanaka’s method (MTM) is often used in the mechanics of composite materials (see review of Christensen, 1990) and received a theoretical support in the recent work of Benveniste (1990). It was applied to a 2-D cracked solid by Benveniste (1986); note that a similar analysis for the 3-D cracked solid was done earlier by Kanaun (1980, 1983). In the case of randomly located cracks, predictions of MTM coincide with those of the more general method of effective field and, again, coincide with the predictions of the approximation of noninteracting cracks. The underlying

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physical reason for this result is actually clear: it is a direct consequence of the fact that introduction of cracks does not change the average stress in a solid, provided the boundary conditions are in tractions. Therefore, the homogeneous effective field of MTM (into which a representative crack is inserted) is the same as the volume average one and coincides with the remotely applied one. 4. Other Models

a. Models of the Second Order in Crack Density Such models were developed by Hudson (1980,1981,1986) and by Ju and Chen (1992) and Ju and Tseng (1992). They calculate effective stiffnesses and effectivecompliances, respectively, to the second order in crack density, in the cases of randomly oriented and parallel cracks. The results of Hudson were plotted by Sayers and Kachanov (1991). As seen from these plots, at low crack densities the results follow predictions of DS; at moderate-to-high densities (on the order of p = 0.2 for parallel cracks and p = 0.6 for randomly oriented cracks, in 3-D), they start to exhibit a physically meaningless behavior: the stiffness increases with increasing crack density. The results of Ju et al. are free of this inconsistency. However, it seems that the authors do not properly address the (difficult) problem, related to geometrical probabilities, of avoiding crack intersections; it is unclear whether this inaccuracy introduces errors of the same order of p z or not. Note that, in the case of parallel cracks, the coefficient at the p2-term differs from that calculated by Horii and Sahasakmontri (1990); the reason for the difference is not fully clear to the present author. In view of the results of Section I, as well as results of MEF and MTM, it appears that if locations of the crack centers are random, then there is no need in the second-order theories, since the approximation of noninteracting cracks remains accurate at high crack densities. Such theories can be useful (assuming the second-order term is properly constructed) in the case of nonrandom crack locations, since they are capable of incorporating, in an approximate way, the information on mutual crack positions. If models of this kind are to be used, it is desirable to estimate the interval of p where the second-order term actually provides an improvement over the linear term (i.e., represents a dominant correction, as compared to the impact of higher order terms).

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We suggest that some insight can be gained by examining the cases when the effective properties are known. One of them is the case of cracks with randomly located centers, for which the approximation of noninteracting cracks yields accurate results. For illustration, consider the 2-D case. If the crack orientations are random, then Young's modulus is E/Eo = (1 + np)-'. Expanding into powers of p and retaining terms to the second order yields

E/Eo = 1 - np

+ n2p2

Two comments on this expression should be made. First, at the crack densities higher than 0.12-0.15this formula starts to yield substantial errors. Second, starting from the crack density p = 0.16, this expression shows a physically meaningless behavior: the stiffness increases, as p increases. In the case of parallel cracks, expanding, in a similar way, the expression E/Eo = (1 + 2np)-' for the modulus in the direction normal to cracks yields: E/Eo = 1 - 2np + 47c2p2.This formula starts to yield unacceptable errors at p = 0.06-0.07 and shows an anomalous behaviour (the stiffness increases, as p increases) starting at p = 0.08. One may conclude, on the basis of this data, that the interval of p where the second-order term provides an improvement over the linear one can be expected to be quite narrow; in the 2-D case, the second-order theories may become unreliable at the point where reduction of the effective moduli is of the order of 25%. In the 3-D case, this interval may be wider, since the 3-D configurations are, generally, less sensitive to various simplifications. b. Model for an Array of Parallel Cracks of Very High Density

Wu and Chudnovsky (1990)considered an array of parallel cracks in the limit of very high density. They suggested a beam model for calculation of the Young's modulus in the direction normal to cracks and found upper and lower bounds based on the assumptions of clamped beams and simply supported beams, respectively.

c. On Bounding the Efective Moduli Bounding the effective moduli, used in the mechanics of composites, is usually understood as applicable to any possible arrangement of inclusions of the given density (the latter being the inclusions' volume fraction). In the case

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Mark Kachanov

of cracks, bounds other than the trivial (stating that cracks do not increase stiffness)in this strong sense-as applicable to any possible arrangement of cracks of the given density p-cannot be established. As shown in Section K, crack arrays of infinitely high p that produce an infinitesimal impact on the effective moduli can be constructed, as well as arrays of infinitesimal p that reduce the stiffnessto zero. This may be related to inadequacy ofthe commonly used crack density purumeter p (or its tensorial generalization a) in the case of nonrandom locations of crack centers; see Sections K and L for discussion. Willis (1980)found a bound in a much milder sense: for parallel cracks with uncorrelated positions of crack centers (“well-stirred approximation,” in his terminology), the approximation of noninteracting cracks constitutes the upper bound for the effective Young’s modulus in the sense of bounding the ensemble average. I.

EXPERIMENTS ON DETERMINISTIC ARRAYS(SOLUTION INTERACTION PROBLEM FOR SAMPLE CRACKARRAYS)

COMPUTER

OF THE

Solutions for deterministic arrays of arbitrary geometry can be produced, by relatively simple means and with good accuracy, using the method of analysis of crack interactions outlined in Section 111. The method yields average tractions on cracks (ti) (as a solution of the system (3.11)). Introducing the proportionality relation ((2.13), in the 2-D case) between (ti) and the average CODs (b’) into the representation (6.5) for the elastic potential, we obtain the effective properties for a solid with the given arrangement of cracks. Such computer experiments on sample arrays can be used to verify various approximate schemes. To check the accuracy of the computational scheme, the procedure was supplemented, in several trial runs, by an alternating technique that enhances accuracy; it was found, however, to be unnecessary-the basic method was quite accurate. 1. Computer Experiments

Sample 2-D crack arrays consisting of 25 cracks were generated with the help of random number generator, as realizations of certain crack statistics. Two orientational statistics were examined: randomly oriented cracks and parallel cracks. For each, six crack densities were assumed p = 0.10; 0.15; 0.20; 0.25; 0.30 and 0.35(in 2-D, the densities of 0.30-0.35 can be considered high). Fifteen sample arrays were considered for each density.

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Locations of cracks within the representative area were random; i.e., positions of crack centers were uncorrelated. For parallel cracks, generation of such arrays was straightforward. For randomly oriented cracks, crack intersections had to be avoided; this was achieved by generating cracks successively and discarding the newly generated one if it intersected already existing cracks and generating it again. Although such a procedure, strictly speaking, violates the condition that crack centers are uncorrelated, we assume that it does not create errors of a systematic sign. Accuracy of the method was checked by supplementing it, in several trial runs, by the alternating technique (stress “feedback”) for improved accuracy, until three-digit accuracy for the effective moduli was reached, and examining the correction obtained. The correction was always insignificant (within 2373, confirming accuracy of the basic method. To be confident in accuracy of the basic method in all cases, the spacing between cracks was not allowed to be overly small: space was kept no smaller than 0.02 of the crack length in the case of randomly oriented cracks and, for parallel cracks with significant “overlap,” no smaller than 0.15 of the crack length. (Retaining configurations with arbitrarily small spacing between cracks would have required stress feedbacks, or some other accuracyenhancing technique, applied to a large number of crack arrayscomputationally, an overly intensive procedure). As discussed in Section G, in the case of parallel cracks this constraint may have introduced a slight “bias” against the amplification mode of interactions. In the case of randomly oriented cracks, each array was examined for isotropy: the effective Young’s modulus was calculated in two perpendicular directions and only those arrays were kept for which the difference between these two moduli was smaller than 2%; the Young’s modulus was then taken as the average over these two values. (We note that preferential orientations causing variation of E with direction up to 6-7% are usually not discernible by a “naked eye”). Figure 51 shows two of the generated arrays. As discussed in Section A, the representative area is assumed to constitute a part of a statistically representative, the average tractions along l- will differ insignifiA are assumed constant and equal to the remotely applied ones. This assumption is rigorously correct for noninteracting cracks, when cracks inside A do not experience any influence of those outside A. For interacting cracks, tractions fluctuate along r, but, if A is sufficiently large to be statistically representative, the average tractions along will differ insignificantly from the remotely applied ones (see the discussion of Section A). Substitution of the fluctuating along r tractions by their averages causes a

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FIG.51. Two of the sample crack arrays examined (randomly oriented, p = 0.25, and parallel, p = 0.30).

scatter of the results from one realization of the crack field statistics to another, but is not expected to produce errors of a systematicsign. The results show (Figs. 52 and 53) that, for samples containing 25 cracks, the scatter is relatively small.

2. Results

Figures 52 and 53 present results for the Young’s modulus for randomly oriented and parallel arrays. Vertical bars show scatter of the results from one sample to another. For randomly oriented cracks, the approximation of noninteracting cracks provides surprisingly accurate results, well into the domain of strong

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P FIG.52. Effective Young’s modulus, randomly oriented cracks: results for sample arrays vs. predictionsof the approximation of noninteractingcracks and the self-consistent and differential schemes.

interactions where this approximation is usually considered inapplicable. For parallel cracks, the approximation of noninteracting cracks also provides good results. However, there is a slight but distinguishable tendency for the stiffening overall effect of interactions,indicating a slight dominance of

P FIG. 53. Effective Young’s modulus, parallel cracks: results for sample arrays vs. the approximation of noninteracting cracks and the differential scheme.

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the shielding mode of interactions. We hypothesize that this slight “bias” in favor of shielding was caused by the prohibition for the crack tips to be overly close to each other. We also calculated the shear modulus for parallel crack arrays (for two arrays, with p = 0.1 5 and 0.20). It differed from the predictions for noninteracting cracks by less than 1.5%.

3. Preservation of Orthotropy for Interacting Cracks We examined the deviation from orthotropy caused by interactions (as discussed in Section B, for noninteracting cracks orthotropy coaxial to the crack density tensor a is a rigorous result in 2-D). We solved the interaction problem for the array consisting of two families of parallel cracks of equal density inclined at 30” to each other. At the overall density p =0.24 (significant interaction) the deviation from orthotropy produced by interactions was found to be very small: in the principal coordinate system of a the nonorthotropic compliances A M 1 1 2 and A M z z l 2 were on the order of 10-3-10-4 of the orthotropic compliances; i.e., indistinguishable. This means that not only the values of the moduli predicted by the approximation of noninteracting cracks remain accurate at high densities, but that the symmetry of the effective properties (orthotropy) predicted by this approximation is retained as well. This implies that characterization of crack arrays by the crack density sensor and the approximation of noninteracting cracks remain fully adequate at high crack densities.

4. Discussion

The underlying reason for accuracy of the approximation of noninteracting cracks is not that the interactions can be neglected, but that the competing effects of stress shielding and stress amplification balance each other (provided locations of crack centers are random). In the language of stress superpositions(Fig. 8), the additional tractions Atji will be of both amplifying and shielding signs on different cracks; on average, their impacts will cancel each other. We emphasize that this conclusion assumes the absence of “bias” in crack statistics toward either amplifying or shielding arrangements. Otherwise(in “ordered” arrays, for example) the impact of interactions can be very large, in the directions of both “softening” and “stiffening.” The reported results are for the 2-D configurations. The approximation of noninteracting cracks is expected to remain accurate in 3-D as well, due to

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the same mechanism of cancellation of shielding and amplification effects. Moreover, we expect the scatter of the results to be smaller, since interactions are, generally, weaker in 3-D (Section 1V.A.).

5. Remarks on Naturally Occurring Crack Arrays The conclusion on accuracy of the approximation of noninteracting cracks is based on the assumption of randomness of crack locations. Such randomness may not always be the case in naturally occurring crack systems. A crack may enhance nucleation of new cracks in its amplification zone and suppress it in the shielding zone, thus creating an amplification “bias.” This may be relevant for the stages of microcracking when localization is about to occur. As an opposite example, the observations of Han and Suresh (1989) on microcracking in ceramics seem to indicate (although not fully conclusively) some shielding “bias” in most (but not all) microcracking geometries (Suresh and Kachanov, to be published). In such cases, the results of this section should be used with caution.

J. COMPUTER EXPERIMENTS ON CRACK ARRAYSIN

AN

ANISOTROPICMATRIX

This section summarizes the results of Mauge (1993) and Mauge and Kachanov (1992) on the effective elastic properties of a 2-D orthotropic matrix with arbitrarily oriented interacting cracks. This problem was solved for a number of sample crack arrays (similarly to the case of isotropic matrix). A strong anisotropy of the matrix was assumed: the ratio of Young’s moduli E,/E, in two principal directions of orthotropy was 10. Two statistics of crack orientations were considered: random orientations and parallel cracks. In the latter case, the cracks were parallel to one of the principal directions of orthotropy. Crack density was increased in steps, from 0.10 to 0.25. The locations of crack centers were random. Fluctuation of the results from one sample of a given crack statistics to another was somewhat higher than in the case of isotropic matrix (this is explained by the fact that the anisotropy of the matrix, which was quite strong in our experiments, enhances the interaction effects and thus increases the scatter), but remained, in r..ost cases, within 5%. For each array, the effective properties were found (1) in the approximation of noninteracting cracks and (2) solving the interaction problem for this

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particular array. The conclusions were similar to those for the isotropic matrix. Namely, in the case of randomly oriented cracks, the interactions did not change the effective stiffness (as compared to predictions of the approximation of noninteracting cracks). In the case of parallel cracks, interactions produced a slight stiffening effect. The methods of an effective matrix, in particular, the self-consistent scheme, substantially underestimate the effective stiffness. The underlying reason is that the impact of interactions on a given crack is simulated by a reduced stiffness of the surrounding material; therefore, interactions are predicted to always reduce stiffness. This ignores the shielding mode of interactions (that balances the amplifying one) and thus distorts the actual mechanics of interactions. On the other hand, our results are in full agreement with the predictions of the method of an effectivefield (which takes the statistics of crack centers into account) for the case of random locations of crack centers, and with the simplest version of this method-Mori-Tanaka’s scheme.

K. ON BOUNDINGTHE EFFECTIVE MODULI Bounding the moduli, widely used in the mechanics of two components materials, degenerates for cracked solids: neither lower nor upper bounds (other than trivial ones stating that cracks do not increase the stiffness) can be constructed, at least, in the sense of bounding that is valid for any particular sample of a given crack statistics. Bounding in a much milder sense-applicable to the ensemble average-was constructed by Willis (1980) for parallel cracks with uncorrelated locations of crack centers (upper bound for the effective stiffness). We note that the opposite statement-that the approximation of noninteracting cracks provides the upper bound for any crack statistics-was made by Gottesman et al. (1980). Such a general conclusion (implying that interactions always reduce stiffness, compared to the approximation of noninteracting cracks) seems to be an overstatement: in statistics biased toward shielding arrangements (stacked cracks, for example), interactions produce the srifening effect. To demonstrate the impossibility of bounds that are valid for any realization of a given orientational distribution, we construct two types of configurations: A. One with crack density p

+ 00 that produces a vanishingly small effect; B. One with p -+ 0 that, nevertheless, makes the stiffness vanishingly small.

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We restrict attention to 2-D geometries and the cases of isotropic and transversely isotropic effective properties. In the case of isotropic effective properties, we first establish a fully symmetric hexagonal mesh (H is a side of a cell) and then consider the following two configurations: A. Radial crack patterns contained within circles of radius r are placed at vertices of the mesh. Making radial patterns arbitrarily dense, while keeping the circle radii sufficiently small (r << H) produces a configuration where an arbitrarily large crack density p produces a vanishingly small impact on the effective moduli (Fig. 54). B. Three families of periodically spaced collinear cracks (crack length is 21 and ligaments between cracks are A) are placed along the mesh (Fig. 55). Both 21 and A are then made progressively smaller, in such a way that A decreases faster than 21. Namely, assuming that H contains N periods: N ( 2 l + A) = H , we set 21 = H / ( N + 1) and A = H / ( N 2 + N). Then considering an elementary cell and calculating the crack density, we obtain p = (4&’N/(N 1)2. We let N + 00, then the total relative length of ligaments N A / H = 1/(N + 1) -+ 0 and, therefore, the efectiue stifness -+ 0. At the same time, p -+0. We further note that, since p and NA/H are independent of H , the parameter H can also be set to -0 as N increases (say, H = H , / N ) . This creates a fine “mist” of infinitesimal cracks that is dense everywhere while possessing the property that the effective Young’s modulus E -+ 0 and, at the same time, p 0. In the case of transversely isotropic effective properties, configuration of type A is constructed as a doubly periodic rectangular pattern of parallel

+

--f

FIG.54. Crack array of infinite crack density, p effective moduli.

+ 00,

producing an infinitesimalimpact on the

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FIG.55. Crack array of infinitesimal crack density, p + 0 that reduces the effective stiffness to zero. Note that this effect is achieved withour violating a coherence of the representative area. The array is dense everywhere (since H + 0).

cracks; spacing between different columns is kept sufficiently wide, while the density of packing within each column + 00. Configuration of type B is constructed as the same pattern, with vanishingly small ligaments between collinear cracks and widely separated rows. We emphasize that the statement on the impossibility of bounds assumes that any possible arrangement of crack centers is allowed. If restrictions are imposed on the statistics of crack centers then nontrivial bounding may be possible. The impossibility of bounding seems to be related to inadequacy of the commonly used crack density parameter p (or its tensorial generalization a) in the case of nonrandom locations of crack centers, due to its insensitivity to mutual positions of cracks. This issue is discussed in the next section.

L. ALTERNATIVE CRACK DENSITY PARAMETER 1. Remarks on the Conventional (Crack Location Insensitive)

Crack Density Parameters

Both the scalar crack density p and its tensorial generalization a are insensitive to mutual positions of cracks. This is fully adequate for either noninteracting cracks (in which case the mutual positions of cracks do not matter) or for interacting cracks provided locations of the crack centers are random. This, however, becomes inadequate for interacting cracks with nonrandom mutual positions, when crack statistics is “biased” toward either shielding or amplifying arrangements. For example, the conventional crack density parameter does not reflect the fact that introduction of a large number of cracks into a shielded zone produces only a small effect.

Elastic Solids with Many Cracks and Related Problems

41 1

This inadequacy manifests itself in the impossibiiity of bounding in terms of p. Another manifestation of inadequacy of p is nonequivalence of the assumption of noninteracting cracks to the assumption of small crack density (as demonstrated by the example of an array of infinitesimal p that reduces the stiffness to zero)-an undesirable feature for a physical theory (and absent in the theory of composites, where volume fractions are used as density parameters). 2. Alternative Crack Density Parameter An alternative parameter that is sensitive to crack positions and, in the case of noninteracting cracks, reduces to the crack density tensor a (or the scalar density p for randomly oriented cracks) can be constructed as follows. We restrict our consideration to the 2-D case; extension to 3-D is straightforward. We recall that the change Af in the elastic potential due to cracks has the form Af = (1/A)

c

(n.a.(b))’l’

(6.86)

i

Making use of the fact that the average COD is approximately proportional of the average traction: ( b ’ ) = ( n l i / E o ) ( t i ) and finding the latter in terms of the transmission factors, we obtain Af

= (n/E0)a : w :u

(6.87)

where the fourth-rank tensor (6.88) which emerges in the elastic potential, accounts not only for the crack sizes and orientations but for the mutual positions as well and can be used as a crack density parameter. In the case of noninteracting cracks, we recover characterization of a crack array in terms of (crack location insensitive)crack density tensor a.Indeed, in this case Roo = 6”I so that U : W : U = @-@:a and Af reduces to the expression (6.15)in terms of a. Thus, w is a generalization of the crack density tensor that accounts for crack interactions and is sensitive to the mutual crack positions. We note that smallness of w means smallness of a sum of products (a-type terms) x (R-terms); the a-terms, as seen from their definition (Section 111),

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Mark Kachanov

characterize average tractions on cracks as fractions of the tractions in the absence of interactions. Thus, the R-terms are small in the case of shielding and large in the case of amplification. Therefore, if o (rather than p or a) is used as a parameter, “paradoxical” situations when infinitesimal crack density reduces the effective stiffness to zero, or an infinite density producing only an infinitesimal effect are eliminated. Indeed, for a dense radial pattern of Fig. 54 (or densely packed stacks of parallel cracks) the conventional density p may be large, but o is small, since the R-terms are small (due to a strong shielding). On the other hand, for the hexagonal pattern of Fig. 55 the parameter o is large (although the conventional density p --* 0) due to a strong amplifying effect of interactions. Another undesirable feature-nonequivalence of the assumptions of noninteracting cracks and of small crack density-is also eliminated, since o is small ifand only ifthe impact of cracks on the effective properties is small. 3. Relevance of o for Randomly Located Cracks and “Ordered” Arrays

Generally, the evaluation of o requires solving the interaction problem (unavoidable, though, if one attempts to incorporate the information on mutual positions). For randomly located cracks, however, the approximation of noninteracting cracks yields good results. Therefore, the description in terms of p or a remains adequate, and switching to the description in terms of o is unnecessary. For “ordered” arrays that may have “bias” toward shielding or amplification, deviations from the predictions of the approximation of noninteracting cracks may be very large. Then, the use of o appears to be important. At the same time, evaluation of o for such arrays seems a more realistic task, since a number of available solutions (as well as approximate results produced by the method of effective field) can be utilized. VII. On Correlations between Fracturing and Change of Effective Elastic Moduli. Some Comments on Brittle-Elastic Damage Mechanics It is argued that, contrary to the spirit of many damage models, there is no stable quantitative correlation between fracturing of a brittle microcracking solid and the change of its effective elastic moduli (with the obvious exception of the immediate vicinity of the fracture point, when the effective stiffness

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413

abruptly drops to zero). Therefore, the change of effective moduli may not always serve as a reliable indicator of the progression of a microcracking solid toward fracture. Physically, the absence of such a correlation is explained by the fact that the fracture-related quantities (like SIFs) are determined by local details of the microcrack field geometry whereas the effective moduli are volume average quantities, relatively insensitive to such fluctuations. This discussion is relevant for a number of damage models that are aimed at a description of thefracturing of a brittle microcracking solid, but in fact deal with its effective elastic moduli; sometimes damage is even deJined as the change in elastic moduli (see, for example, Wang, Chim, and Suemasa, 1986; for reviews, see Krajcinovic, 1989, and Maugin, 1992, Chapter 10). The underlying idea-that progression toward failure is uniquely correlated with the change of effective moduli-may seem intuitively reasonable; it appears particularly attractive because the moduli can be easily measured. It seems that, for such correlations to be useful, they should be formulated in quantitative terms. An objection may be raised that, as is well known, a small crack in a brittle material has a very small impact on the effective stiffness but may drastically reduce the tensile strength. One may argue, however, that, after a certain initial set of defects has been nucleated and started to grow, the quantitative correlation can be established. This idea is examined here from several points of view. A. MICROCRACKING AND

THE

CHANGE OF ELASTIC MODULI

1 . “Paradoxical” Example

To demonstrate that this idea is far from obvious, we start with a simple example when the correlation between SIFs at the crack tips (fracture-related quantities) and the effective moduli is “paradoxical.” Consider a plate containing stacks of parallel cracks (Fig. 56, solid lines) and assume that additional cracks are introduced in between the neighboring cracks (dashed lines). The introduction of new cracks reduces elastic stiffness in the direction normal to cracks-the material elastically softens. However, the SIFs decrease (due to increased shielding)-the new cracks have a strengthening effect.

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FIG.56. Introduction of new cracks (dashed lines) reduces the SIFs and, at the same time, elastically “softens” the material.

2. Random Crack Arrays It may be argued that the preceding example does not represent any realistic crack statistics (although such parallel crack patterns do occur in rocks and certain composites) and that, for more random arrays, progression toward failure can be quantitatively correlated with the reduction of elastic stiffness. To demonstrate that such a correlation is not obvious, we did the following computer experiments. A number of two-dimensional crack arrays containing randomly oriented cracks of the same length were generated and subjected to a uniaxial loading; statistics of crack centers was also random (subject to the constraint that cracks do not intersect).For each sample array, using the method described in Section 111, we calculated 1. the effective Young’s modulus Ecff, 2. the maximal, among all crack tips, value of Kf + K i . (Strictly speaking, this parameter determines initiation of crack propagation only for rectilinear crack extension; if both K Iand KIIare present, a certain other combination of K , , K,, is a relevant parameter. Typically, however, this combination does not differ much from K f + K i . ) We found that, whereas Eeff was quite stable from one statistical sample Ki)Juctuated signiftcantly, reaching higher values in to another, max(K: larger samples where the probability of occurence of closely spaced cracks is higher. Thus, Eeff stabilizes as the size of the crack sample increases (usually, at the number of cracks on the order of 10) whereas the fracture-related parameter max(K: + K i ) is statistically unstable and increases as the size of the crack sample increases.

+

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415

3. Strong and Weak Interactions. Clustering of Cracks Interactions that produce a strong impact on the SIFs may be weak in their impact on the effective moduli (see the discussion of the case of small transmission factors in Section 111). A closely related issue is that the clustering of cracks strongly affects the SIFs. Figure 57 provides an illustration: max(K: + K i ) is, typically, substantially higher in configurations of the type 57b than in ones of the type 57a. On the other hand, sensitivity of the effective elastic moduli to clustering is low, i.e., the difference in moduli of the configurations 57a and 57b is, generally, small (provided the overall crack density is the same). Thus, monitoring the change in effective elastic constants may not necessarily detect the onset of strong crack interactions and clustering of defects, events that are crucially important from the point of view of progression toward failure.

Fro. 57. Clustering of cracks strongly affects SIFs (fracture-related quantities) and leaves the effective moduli almost unchanged.

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Mark Kachanou

4. Efect of the Crack Shape Consider a 3-D elastic solid containing elliptical cracks. As is well known, the profiles of SIFs along the crack edges and their maximal values depend on the aspect ratios of the ellipses. At the same time, the shapes of cracks have very little impact on the overall effective elastic stiffness (see the discussion of noncircular cracks in Section VI).

5. Crack-Microcrack Interaction Problem In the crack-microcracks problem (discussed in Section V), the absence of correlation between the effective moduli and the fracture-related properties is apparent: microcracks located in the short-range interaction zone (several microcracks closest to the main crack tip) produce a dominant impact on the main crack tip. Due to a high sensitivity of the interaction effect to the exact positions of closest microcracks, the impact of microcracks on the main crack SIFs fluctuates significantly and even qualitatively (from shielding to amplification) from one sample of the microcrack statistics to another. This means that there is no statistically stable effect ofstress shielding, at least, if the microcrack locations are random. On the contrary, being conservative, one may conclude that the overall effect of interactions is the one of enhancement, particularly in 3-D where local peaks of SIFs along the crack front are almost always present. On the other hand, replacing the microcracked region by an “effective” material of reduced stiffness would produce a different result-that interactions result in shielding.

6. Cases when Progression Toward Fracture Can be Monitored by the Change of Effective Moduli The basic underlying reason for the absence of the one-to-one correspondence between fracturing and change of the effective elastic moduli is that the fracture-related quantities (like SIFs) are determined by local fluctuations of the microdefect field geometry whereas the effective elastic properties are uolume auerage quantities, relatively insensitive to such details. Therefore, when the evolution of the defect’s population follows a more or less deterministic reproducible pattern, the progression toward fracture may indeed be monitored by reduction of the effective stiffness. Such situations occur in certain laminated composites where such patterns were called characteristic damage states by Reifsnider and Stinchcomb, 1983. Note, however, that correlations were not straightforward even in these cases. As their data shows, (1) correlation between the fraction T of the remaining lifetime of a specimen and its effective stiffness E held only for a given

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417

arrangement of layers: for different ply orientations (and, therefore, different crack patterns), the E-T curve was different; (2) of the three E - T curves, given by the authors, one remained almost p a t (stiffness was almost insensitive to damage accumulation) and another one was changing rather weakly during most of the lifetime. A possible explanation is that, during most of the lifetime, fracturing processes did not raise the overall microcrack density to the levels at which stiffness reduction becomes significant. B.

ELASTICPOTENTIALS IN TERMS OF DAMAGE PARAMETERS

O N THE CONSTRUCTION OF

1. Elastic Potentials and Efective Properties One of the approaches of brittle-elastic damage mechanics is to postulate a certain form of elastic potential in strains-strain energy density-that contains an additional damage parameter D (scalar or tensorial): W = W(E,D);see, for example, Lemaitre and Chaboche (1978); for reviews with further references, see Maugin (1992) and Krajcinovic (1989). Such formulations are, apparently, motivated by the successes of this approach in the theory of creep, where the notion of damage first appeared, in the pioneering work of L. Kachanov (senior) (1958). However, a straightforward application of this idea to the brittle-elastic case may lead to problems. We first note that, if a model for the efective elastic properties is available, such a model fully specijes W(E,D). If the damage is formed by microcracks with randomly located centers, D is the crack density tensor a,reducing to the scalar crack density p for randomly oriented cracks (if the locations of crack centers are not random, their statistics can be incorporated into description through the damage parameter o,see (6.88)). In this case the complementary energy density f = f ( q a ) was constructed in Section VI; it may be Legendre transformed to strain energy density W When damage is formed by cavities, or by a mixture of cracks and cavities, several models for the effective elastic properties are also available (see, for example, Kachanov, 1993), so that W can be fully specified in this case as well. It appears, therefore, that the main motivation for postulating (rather than deriving) W is that the geometry of damage elements is not known, with the hope that the uncertainties can be taken care of by an appropriately chosen form of W We note that any such formulation, regardless of other applications, necessarily implies a certain model for the efective elastic moduli (taking derivative a W/ac at fixed D yields elastic stress-strain relations, with

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Mark Kachanov

moduli-functions of D). Therefore, such constructions should be consistent with the known results on the effective moduli, when damage is formed either by microcracks or cavities. A particular attention should be paid to the case of small D,when the results are rigorous and well known. Here, we comment on several related developments in damage mechanics.

2. Choice of Damage Parameters In some models, the damage parameter is taken as characterizing the “area loss” due to defects (see Murakami and Ohno, 1981; Betten, 1982 gave a general discussion of tensorial parameters of this kind). Such definition of damage is motivated by the aforementioned work of L. Kachanov, where damage accumulation under creep conditions was considered. However, damage parameters that are appropriate in the theory of creep may not be adequate in the theory of effective elastic properties, since microcracking affects creep and the effective moduli in entirely different ways. The process of creep is enhanced by damage due to tensile stress concentrations in zones near defects (these zones can be substantially larger in a creeping solid than in a linear elastic solid). In agreement with this mechanism, the damage parameter in L. Kachanov’s model is introduced in such a way that it couples the processes of damage development and creep and describes a self-accelerating nature of creep accompanied by damage. In the problem of effective elastic properties, on the other hand, stress concentrations are irrelevant-it is the average stress that enters formulation of the problem (and it is not affected by stress concentrations; zones of elevated stress are balanced by shielded zones of reduced stress, see Section V1.A). Therefore, damage parameters in the theory of creep and in the theory of effective elastic properties may not coincide. When damage is formed by microcracks, the proper damage parameter for the problem of effective elastic properties is dictated by the elastic potential: it is the crack density tensor a. If, instead, a diferent damage parameter is used, this may lead to inconsistencies. (For example, the above-mentioned tensor describing cross-sectional area losses seems to possess the property that contribution of a given crack into such a tensor is proportional to the crack area; i.e., to its linear size squared. On the other hand, an individual crack’s contribution to p or a is proportional, in the 3-D case, to its size cubed. This means that use of the area loss-related tensors in the elastic potential would distort relative contributions of individual cracks into the overall elastic properties. In the case of non-randomly oriented

Elastic Solids with Many Cracks and Related Problems

419

cracks, it would lead to incorrect predictions of the overall anisotropy.) Similarly, if damage is formed by spherical cavities, their relative volume is the parameter relevant for the effective elastic properties; altering it may lead to inconsistencies.

3. On Models of the W = (1 - D)Wo n p e It has been suggested in a number of papers (see Lemaitre and Chaboche, 1978, for example) that the elastic potential in strains-the strain energy density of a damaged solid-can be written in the form W(E,D ) = (1 - D)WO(E)

(7.1)

where D is some scalar measure of damage and Wo is the potential without damage. (This form is, obviously, limited to isotropic damage; an application of it to parallel cracks, for instance, yields equal stiffnesses in the directions normal and parallel to cracks). The model (7.1) has some inconsistencies.One of them was pointed out by Ju (1990):the Poisson’s ratio is unaffected by damage-a wrong prediction. (We note two special cases when Poisson’s ratio is, indeed, unaffected by damage. In the first case, damage is formed by spherical cavities and Poisson’s ratio vo of the undamaged matrix is exactly 0.2; then the effective v is unaffected by damage, at least, in the approximation of noninteracting cavities. In the second case, a mixture of cracks and spherical cavities is present and vo < 0.2; since cavities increase v whereas cracks reduce it, one can design a special ratio (dependent on yo) of the crack density to the density of cavities such that it enforces constancy of v.) We add that, in the simplest case of a small D,the model’s predictions of the effective moduli are not consistent with the rigorous results for noninteracting defects of small density, whether these defects are cracks or cavities and D is understood as a usual measure of their density (and the only one acceptable in the elastic potential). Indeed, in the 3-D case of randomly oriented circular microcracks of small density (the case of noncircular cracks can be reduced, with high accuracy, to the case of equivalent circular cracks, see Section VI.B.8) W can be written exactly, as a sum W = Wo+ A W of the potential Wo without cracks and the change A W due to cracks, where WOW =

Mark Kachanov

420

and AW(E)=-

8E0( 1 - v0M1- v0/5)

+

9(1 - ~0/2)(1 vO)

vo(vg - 16v0 EiiE’i

+ 19)

+ 1q1 - v0/5)( 1 - 2v0)’

(Ekk)2]

(7.3)

For the representation Wo + AW

= (1

- D)Wo

(7.4)

to be possible, the coefficients at (ckk)2 in (7.2) and (7.3) should be identical or, at least, close (in which case, D would, of course, be nothing but p , to within a multiplier). This is not the case (unless vo = 0): for vo = 1/3 and vo = 1/4, for example, these coefficients differ 4.4 times and 2.5 times, respectively. A similar problem arises in the case of a small concentration of a mixture of cracks and cavities (although, formally speaking, a special ratio of the crack density to the density of cavities can be designed, such that (7.4) is enforced to be correct, provided vo < 0.2).

4. Damage as an Adjustable Parameter

Models of the type of (7.1) can, of course, be interpreted in a different way: D can be understood as simply an adjustable parameter, defined in such a way as to enforce (7.1) to be correct; i.e., (7.1) serves as a dejnition of damage. In this case, D may not be interpreted in terms of microstructural quantities. Since the geometry of the damage elements may not be known, there is a certain motivation for such an approach. We note that, if such an interpretation is assumed, then Ju’s argument on constancy of Poisson’s ratio still remains valid, indicating that W cannot be written in the form (7.1). Thus, even if D is understood as simply an adjustable parameter, it still cannot be defined in such a way as to make (7.1) correct. It has been suggested to modify (7.1) by “upgrading” scalars 1 and D to fourth-rank isotropic tensors (Ju, 1990). Then the number of adjustable parameters increases from one to two and Poisson’s ratio does not have to be constant. I t seems, however, that a more straightforward way to introduce two adjustable parameters in the elastic potential is to directly treat two efective moduli as such parameters. (General problems that arise from association of fracturing with changes in moduli, will, of course, remain, see Section VILA).

Elastic Solids with Many Cracks and Related Problems

42 1

VIII. Effective Elastic Properties of Solids with Elliptical Holes This Section analyzes the effective moduli of a 2-D elastic solid with elliptical holes. The 2-D modeling is relevant for materials with porous structures that are approximately “tubular.” Besides, results in 2-D allow direct verification by computer experiments on sample arrays of holes, by finite elements, spring force modeling or other techniques (see Section VI and Mauge and Kachanov (1992) for numerical experiments on cracks and Day et al. (1992) for numerical experiments on circular holes). An extensive study of 2-D pores of various shapes was done by Zimmerman (1986, 1991). His work, however, focuses on the compressibility of holes (change of the hole area under the hydrostatic stress). As far as derivation of the full set of efective moduli is concerned, the works of Thorpe and Sen (1985) and Zhao and Weng (1990) should be mentioned. Thorpe and Sen gave results for randomly oriented holes in the approximation of the self-consistent model (which may substantially overestimate the eflective compliance, particularly for narrow, crack-like holes; see Section VI). Zhao and Weng considered composites with elliptical inclusions of “tubular” structure (plane strain) for two cases of orientational distribution (randomly oriented and parallel inclusions); results for holes can be obtained from their results by letting the inclusions’ stiffness go to zero. Our analysis represents a further progress in these studies. A unijied description covering both holes and cracks (or their mixture) is developed. It yields a full set of (generally, anisotropic) moduli for an arbitrary orientational distribution of holes of various aspect ratios. The approach eliminates degeneracies in the models describing the moduli in terms of the area fraction of holes, which arise in the limiting case of cracks (unless special care is taken in the transition to the limit). The key point in our analysis is the identification of proper parameters of density of holes. The choice of such parameters is not arbitrary, but is dictated by the structure of the elastic potential. It is shown that two density parameters are needed: one scalar, the porosity p (which vanishes in the case of cracks), and one second-rank tensor, the “holes density tensor” 0 (which reduces to the crack density tensor in the case of cracks and is proportional to the unit tensor in the case of circular holes). Even in the case of random orientational distribution of holes (isotropy), the effective moduli cannot be characterized in terms of porosity alone-a second parameter, “eccentricity,” is needed.

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The effective moduli are derived in two approximations: (1) the approximation of noninteracting holes, and (2) Mori-Tanaka’s scheme, i.e., by assuming that a representative hole is placed into the aueraye stress in the matrix (which, in the case of holes, can be found exactly). Note that this scheme received theoretical support in the work of Tandon and Weng (1986), Weng (1992), and Benveniste (1990). Two extreme cases-cracks and circular holes-are covered as special cases. For cracks, the hole density tensor fl reduces to the crack density tensor Q (see Section VI) and the known results are recovered. For circular holes, the moduli are expressed in terms of porosity, which remains the only density parameter. A mixture of cracks and holes is analyzed. It is shown that the interaction effect between cracks and holes is “asymmetric”: holes afecr cracks (by changing the average stress environment for cracks) but cracks do not afect holes (since the presence of cracks does not change the average stress, provided the boundary conditions are in tractions). In the case of nonrandom orientations of holes, the effective moduli are anisotropic. The anisotropy is explicitly expressed in terms of the hole density tensor fl and p . The analysis is done in the framework of linear elasticity; nonlinear effects caused by closing of holes by compressive stresses (stiffness increasing with compression, different moduli in compression and tension, etc.) are not covered. This restriction translates, in the case of compressive loading, into a restriction on the magnitude of stresses at which the derived results are valid (see Walsh (1965) and Zimmerman (1991) for estimates of stresses needed to close a hole and produce nonlinear effects). A. ONE ELLIPTICAL HOLEIN

A UNIFORM

STRESS FIELD

We consider a 2-D linear elastic solid containing an elliptical hole with axes 2a and 2b. The macroscopic strain E is given by the usual relation E = M’:u

+ A&

(8.1)

where Mo is the compliance tensor of the matrix. As follows from the divergence theorem (see a footnote in Hill (1963)), the additional strain A& due to the hole is expressed in terms of displacements u of the hole boundary R

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423

(n is a unit outward normal to r and A is the total, including the hole, reference area). Consider a uniaxial loading P inclined at an angle a to the axis 2a of the ellipse (Fig. 58). The intergral (2.2) can be calculated from the known solution of elasticity (see Savin (1970) or Muskhelishvili (1963)) or, alternatively, from Eshelby's results for an ellipsoidal cavity in the limiting case of an ellipsoidal cyclinder. Either calculation yields: P 1

=--

Eo A A ~ 2 2=

nb[b

+ (a + b)cos 2al;

P 1

- - na[a - (a + b)cos 2a];

(8.3)

Eo A

P 17t Ac12= - - (a + b)'sin2a E, A 2

The plane strain conditions are assumed hereafter; therefore, Young's modulus E , entering (8.3)should be understood as Eb(1 - v o )- 1 where Eb, 12

vb are the usual 3-D matrix constants. Other plane strain matrix constants used in the text to follow are expressed in terms of the 3-D constants as vo = vb(1 - vb)-', bulk modulus K O = (1/2)Eb(1 - 2vb)-'(1 + vb)-' (for plane stress, E , = Ebv, = vb, K O = (1/2)Eb(l - vb)-'). Note that K O = (1/2)E0(1- vo)- for both plane strain and plane stress. The following observations on strains Acij due to a hole can be made. produced by a hydrostatic loading The volumetric strain Acl + o I I= 0 2 2= P, is

,+

AE,

P I

= --

Eo A

2n(a2 + b2)

J J FIG.58. Elliptical hole subjected to an arbitrarily oriented uniaxial tension.

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This formula recovers the result of Walsh et al. (1965). We further note that the geometrical parameter a’ + b’ entering (8.4) can be represented as

a’

+ 6’

= 2ab

+ (a - b)’

(8.5)

This simple relation indicates that, among holes of the same area nab, the more “elongated ones have higher compressibility. (Zimmerman (1986) proved this statement for a wider class of hole shapes, showing that the circular hole is the least compliant one). We also remark that the ellipse’s perimeter (given by an elliptic integral) can be approximated by a simple expression 4.22 (a’ + b’)’’’ with the accuracy better than 5.5% for all aspect ratios; therefore, the ellipse’s compressibility can be regarded as approximately determined by its perimeter. Figure 59 shows the compressibility of a hole as a function of the aspect ratio b/a. It is interesting to examine compressibility near the limiting cases of a crack and of a circular hole. At b = 0 (crack), the slope is horizontal, so that a slight “inflation” of a crack leaves the compressibility almost unaffected; the difference is only 1% at bja = 0.1 and 5% at bfa = 0.22. A similar observation in the 3-D case (spheroidal pores) was made by Zimmerman (1986, 1991). (Note that this insensitivity to a small-

2.01

’

’

’

’

’

’

’

’

’

’

circular hole of the same area

I n (v

(d

1.o

0.0

b/a FIG.59. Compressibilityof an elliptical hole as a function of the aspect ratio. Compressibility of the circular hole of equal area is shown for comparison.

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425

to-moderate “fin flation” aggravates the problem of degeneracy arising, in the limiting case of cracks, in the models describing the moduli in terms of porosity.) In the opposite extreme of shapes close to circular, the slope of the compressibility curve coincides with the one for a circular hole of equal area. The compressibility can be approximated by that of a circular hole of the equal area with the accuracy better than 5% for b/a > 0.72 (moderately noncircular hole). due to a hole subjected to a uniaxial The volumetric strain A EI ~+ loading P inclined at an angle c1 to the axis 2a is Ac,

P 1 P I n + Ac22 = - x(a2sin2cc + b2 cos*a) = - - - w2 Eo A Eo A 2

(8.6)

where w is the width of the hole’s profile, as seen in the direction of loading. This implies that various ellipses shown in Fig. 60a produce the same volumetric strain, when loaded in the direction shown. The explanation is that the differences in the normal strain in the direction of loading are exactly balanced by the differences in (negative) lateral strain. Therefore, uniaxial loading of a solid with many noninteracting elliptical holes produces a volumetric strain that depends only on the sum X w;, where w,, is the width of the k t h hole profile in the direction of loading (Fig. 60b). produced by The ratio of the normal “compliance” of a hole (strain

due to a hole is determinedby w z ; (b) Volumetric FIG.60. (a) Volumetric strain A c , , + strain produced by noninteracting holes is determined by the sum Z w:.

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426

the uniaxial loading produced by o ,),

,

02,of

unit intensity) to the shear “compliance” (BeI2

be,, - (a -Ae2,

+ b)’ + b)

(8.7)

a(2a

is quite sensitive to the eccentricity of the hole: it changes from 1/2 for a crack to 4/3 for a circular hole. This is because the normal compliance of a hole is only moderately larger than the one of a crack coinciding with the ellipse’s major axis (1.5 times, for a circular hole), whereas the shear compliance is substantially larger (4 times, for a circular hole). For a general loading 0, the strain A& can, due to linear elasticity, be expressed as A& = H : a

(8.8)

where the fourth-rank tensor H can be called the hole compliance tensor. Using the result (8.3), H is found as follows: H

= -- n

Eo l A1

a(2a + b)nnnn + b(2b + a)mmmm

[

]

+ -21 (a + b),(mn + nmXmn + nm) - ab(mmnn + nnmm)

(8.9)

where n and m are unit normals to the axes 2a and 2b of the ellipse. The first two terms characterize the normal compliances of the hole in the n and m directions; the third term characterizes the shear compliance, and the fourth term characterizes the Poisson’s ratio effect. (In the case of a crack, H = nBn, where B is the COD tensor of a crack; see (6.7).) The elastic potential in terms of stresses (complementary energy density) of a solid with a hole can be represented as a sum of two terms: f(0) = &:E(o) = $o:Mo:a + $ t ~ : H : a

fo

+ Af

(8.10)

where fo is the potential in the absence of a hole and Af is the change in f due to the hole. Utilizing the expression (8.9) for H and using the identities 0:

IS:

(nnnn - mmmm):
=

20 * CJ:nn - tr ( r *0,

[2(nnnn + mmmm) + (mn + nm)(mn + nm)]: cr = 2 tr O - G

(8.1 1)

that follow from the identities nnnn - mmmm = nnI + Inn - I1 and mmnn + nnmm = I1 - (nnnn + mmmm), we transform Af to a form that

Elastic Solids with Many Cracks and Related Problems

427

explicitly reflects the hole geometry:

Af=-

1

1 (nab[4 t r a - o - (tru)’] 2EO A -

+ 2 x 1 ~a:(a’nn . + b’mm - abI)}

(8.12)

The first term in the braces is expressed in terms of stress invariants, and thus describes the isotropic response; it enters with the ellipse’s area as a multiplier. It vanishes in the case of a crack. The second term is orientationdependent; it vanishes for a circular hole.

B. NONINTERACTING ELLIPTICAL HOLES.PROPER PARAMETERS OF DENSITY OF HOLES In the approximation of noninreractiny holes, each hole is subjected to the same externally applied stress IS. Then the additional strain due to holes is CH‘k):o,so that the overall compliance M = Mo + XH‘k). Elastic potential Af is a sum of terms of the (8.12) type: 1 A ~ = u : C H ‘ ~ ) : U = - (p[4tro~a-(tra)’] + 2 0 . a : ( f i - p 1 ) } 2EO

(8.13)

Thus, the potential is expressed in terms of two dimensionless parameters of density of holes, one scalar and one tensorial: p

1 A

= - nC

(ab)‘k) (porosity)

(8.14)

p = - 1 nC (a’nn + b2mm)‘k’ A

Tensor fl can be called a hole density tensor. For cracks, (1/n)fi reduces to the (2-D) crack density tensor a = (1/A)C(a2nn)‘k), see (6.16). Then (8.13) reduces to the potential of a solid with noninteracting cracks: Af = (n/n/Eo)a*a:a, see (6.15). In the opposite extreme of circular holes, fi = PI. The linear invariant t r p = ( l / A ) Z ( a Z+ b2)(k)characterizes the change in compressibility of the solid due to holes (see (8.4)). Thus, Af is a sum of two terms. The first one (proportional to p) does not depend on the orientational distribution of holes. It vanishes in the case of cracks. The second term vanishes in the case of circular holes; it indicates that, at the same level of porosity, the more “elongated” holes produce a higher impact on the effective moduli. We emphasize that the parameters of density of holes-porosity p and

428

Mark Kachanov

the holes density tensor p-are not introduced arbitrarily, but are dictated b y the structure of the elastic potential. Since p is a symmetric second-rank tensor, the effective properties of a solid with elliptical holes are orthotropic, for any orientational distribution of holes. The axes of orthotropy are coaxial with the principal axes of p, which constitute, therefore, a natural coordinate frame for the tensor of elastic constants. This generalizes the fact of orthotropy of a medium with cracks (see Section V1.B). Similar to the case of cracks, the orthotropy is of a simplified type: 1 . The so-called Saint-Venant’s relations (6.20) hold. They reduce the number of independent moduli from four (in the general 2-D case of orthotropy) to three. 2. The orientational dependence of the effective compliances is described by an ellipse (rather than a fourth-order curve, as in the general case of orthotropy).

The difference p - P I entering the potential (8.13) can be called the eccentricity tensor; it can also be written in the form (n/A)X [(a - b)(ann - bmm)](k).Its linear invariant

H

(8.15)

can be called the eccentricity parameter. In the case of circular holes, 4 = 0; in the case of cracks, ( l / n ) q coincides with the conventional scalar crack density p = (1/A)XdkjZ(linear invariant of the crack density tensor a). The effective moduli given by the potential (8.13) are as follows

(8.16)

(the plane strain bulk modulus K is understood as defined by the relation c I + c Z 2 = a/K, where 0 = a1 = oZ2 denotes the applied hydrostatic stress). At p = P I , the results for circular holes are obtained: (8.17)

Elastic Solids with Many Cracks and Related Problems

429

For cracks, p = 0, fi = 7ca and the formulas of Section VI are recovered:

_v -_ - E-

--

E,

1

vo

1

(random orientations);

+ 27cp

(8.18)

_ VI2 El--- 1 -(parallel cracks) VO Eo 1 ZP

+

1. Randomly Oriented Holes (Isotropic Efective Properties)

In this case, fl is proportional to the unit tensor I and, since tr p = 2p + q, 1

fi = ( p + q/2)I so that Af

= - [(4p

2EO

+ 4 ) t r a . o - p(tra)2]

(8.19)

The effective Young's modulus and the bulk modulus K are

E=

Eo . 1+3p+q'

K =

KO 1 + (2P + q ) / ( l - yo)

(8.20)

We emphasize that the effective properties, although isotropic, cannot be expressed in terms of porosity alone: the eccentricity parameter q is also needed. If this factor is ignored (holes are treated as circular), then porosity, as inferred from measurements of the effective moduli, may be substantially overestimated. For example, porosity estimated from the reduction of the bulk modulus K (as compared to its value for the undamaged material) would be exaggerated by a factor of 1 q/2p; if all the holes are identical, this factor is equal to (a/b b/a)/2 - 1 = 1.25 and 1.82 for b/a = 0.5 and 0.3, respectively. On the other hand, if the hole shapes deviate from circles only moderately, the moduli can be approximately expressed in terms of p only. For example, taking K from (8.20) with q = 0 yields errors smaller than 556% if the aspect ratios of all ellipses exceed 0.6-0.7.

+

+

2. Parallel Elliptical Holes (Anisotropic Efective Properties) The hole axes 2 ~ ' and ~ ) 2b(k)are parallel to x2 and x , , respectively (Fig. 61). Then 1

fl = - 7 ~ { [ C a ( ~ ) + ~ ][Ce ~b(k)2]e2e2]} e~

(8.21)

A

We introduce the mean semi-axes and the mean aspect ratio (a2)

1 = - a(k)2,

N

1

( b 2 ) = - C b(k)2; N

-

1:

,I2 = ( b 2 ) / ( a z )

(8.22)

Mark Kachanou

430

0.4 -0.2 -0.0

” ’ : “ “ ’ ” ‘ ” “

where N is the number of holes in the representative area A. The results below can be made more transparent by considering fictitious cracks associated with the ellipses’ axes 2a(k) and using the conventional scalar crack density parameter p = (1/A)Ca(k)2. Then

fi = np(e,e, + 12e,e,) The potential Af is thus expressed in terms of p, p and

Af=-

1

2Ecl

(pC2t1-a-a-(tra)’]

+ 2 x p [ a f l +(1

(8.23)

I: +12a12]f

(8.24)

The ratio of Young’s moduli in the x, and x2 directions is

E, 1 + p + 2xpI2 _ E,

1+p+2xp

(8.25)

In the case when all the holes have the same aspect ratio R (so that p = ZAP), E, _ - 1 + xAp(1

+ 22)

(8.26) 1 xp(2 + A) E, Figure 61 shows this ratio as a function of R; it illustrates a gradual disappearance of anisotropy as the holes are “inflated from the crack-like

+

Elastic Solids with Many Cracks and Related Problems

43 1

shapes to circles. When R is small, this ratio changes rather slowly; for example, it increases from 0.44 at R = 0 (crack) to only 0.49 at R = 0.2, so that the anisotropy due to narrow holes is close to that due to cracks (associated with the ellipses’ major axes). In the opposite extreme, even small deviations of the hole shapes from circles result in a noticeable anisotropy; for example, at A = 0.9 and 0.8, the ratio E J E , is equal to 0.91 and 0.82, respectively. This is in contrast with the case of random orientations, when moderately noncircular holes can be replaced by circles of the same area with good accuracy.

C. INTERACTING ELLIPTICAL HOLES

In the case of cracks, the results of Section VI show that the approximation of noninteracting cracks remains accurate a t high crack densities, provided the mutual positions of cracks are random. The underlying reason-that the competing interaction effects of stress shielding and stress amplification, on average, balance each other-appears related to the fact that introduction of cracks does not change the average stress in the matrix (provided the boundary conditions are in tractions). Therefore, the average stress coincides with the remotely applied one; placing cracks into such a field corresponds to the approximation of noninteracting cracks. Guided by these results, we apply the same approach to elliptical holes with random mutual positions, placing each hole into the average over the solid phase stress cs. In terms of stress superpositions (reduction of a problem with N holes to N problems with one hole each), this means that the interaction tractions induced at the site of a hole (in a continuous material) by the other holes reflect, on average (over all holes), the change of the average stress environment in the solid phase. This approach corresponds to Mori-Tanaka’s model (1973). We note that Mori-Tanaka’s scheme was shown to produce results that lie within Hashin-Strikman’s bounds for randomly oriented ellipsoidal inclusions (Tandon and Weng, 1986) and within Willis’ bounds for parallel inclusions (Weng, 1992). This scheme received further support in the work of Benveniste (1990). For a solid with holes, the average stress in the solid phase Q’ can be found exactly, in terms of the applied (macroscopic) stress c and porosity p . Indeed, application of the divergence theorem to a solid with traction-free holes yields as. 11 /. tJ.. = (1 - p ) -

’

(8.27)

432

Mark Kachanov

Note that all the stress components are raised by the same ratio (1 - p ) - ’ . Thus, placing a representative hole into the average stress, i.e., replacing u by (1 - p)-’u in the hole compliance relation A& = H:u, we obtain the potential Af = (1/2)a:A~ from Af for noninteracting holes by a simple adjustment 1 1 1 Af = - Afnnonin, = - - { p[4 tr u u - (tr a)’] 1 -P l - p 2Eo 0

+ 213 u :(fl - PI)} *

(8.28) where the factor (1 - p ) - ’ reflects the change in the stress environment for holes. The structure of (8.28) shows that the impact of interactions on the efective moduli decreases (defects become, on average, “invisible” for each other) as porosity decreases. In the limiting case of cracks (p = 0), the approximation of noninteracting cracks is recovered, and Af is expressed in terms of the crack density tensor: A! = (n/Eo)u u :a. The effective moduli for interacting randomly oriented elliptical holes are

-

E=

1

+ (3p +EO4x1 - p ) - ’ ’

K =

KO 1 + (1 - p)-’(2p + 4 ) N - V g )

(8.29)

where the factor (1 - p ) - ’ accounts for interactions. Formula (8.29), as well as the special case of the formula (8.30) for parallel holes of identical aspect ratios, can be recovered from the results of Zhao and Weng (1990) on elliptical inclusions, if the inclusions’ stiffness approaches zero. In the case of parallel holes, the anisotropy, as measured by the deviation of the ratio

(8.30) from unity, is enhanced by interactions. In the case of small porosity p (but not necessarily small fl), (8.31) Smallness of p does not necessarily mean that the holes are narrow (p can also be small due to a low density of wide holes). If, however, the holes are

433

Elastic Solids with Many Cracks and Related Problems

narrow, then, to within small values of higher order, ( l / r ~ ) Bcoincides with the crack density tensor a, and 1 rK ---p[2tra*a-(tro)Z] +-(1 2EO EO

71

Af=AfnOnin,+p-a*c:a= EO

+p)o.a:a (8.32)

where the multiplier p at a * a : a reflects the enhancing efect of porosity on cracks.

D. MIXTUREOF

INTERACTING C I R C U L A R

HOLESA N D

CRACKS

This case models microcracking in a porous material and may be of interest for rock mechanics applications. In this case, B is a sum

B = Bholea + Pcracks = P I + za

(8.33)

For a mixture of noninteracting holes and cracks, the potential (8.28) is a sum: Af

=

+

A f ~ ~ AJE:;, ~ ~ ~ = ; &c

+

1

- 0 : ~- - p [ 4 t r a . o

EO

- (tro)’]

2EO

(8.34)

For a mixture of interacting holes and cracks, Af

1

= -Af

1-P

‘I

~[4tro.a--(tra)’]+2n-o.a:a 2E0 1 - p 1- P

. =-

nonlnl

(8.35)

The first term depends on p only (does not depend on crack density a);the second term contains both a and p . This shows that the interaction effect between cracks and holes is “asymmetric”: cracks do not raise the average stress in the solid and, thus, produce, on average, no impact on holes, whereas holes enhance the impact of cracks on the effective moduli (by changing the average stress environment for cracks). Thus, as far as the effective properties are concerned, cracks do not afect holes, but holes afect cracks. If cracks are randomly oriented, a = (p/2)I so that = ( p + 71p/2)I. Then E=

EO

1

+ ( 3 p + ~ p ) ( 1- p ) -

’

K =

K O

1 + (1 - PI-

V P + 71P)/(l - yo)

(8.36)

Mark Kachanov

434

Young’s modulus, as a function of crack density, is plotted for various “background” levels of porosity in Fig. 62. In the case of parallel cracks (normal to the x, axis), u = pelel. Young’s modulus in the direction normal to cracks is (Fig. 63):

E=

Eo

1

+ (3p + 2npX1-

p)-

(8.37)

and the ratio E J E , characterizing the degree of anisotropy is El _ E2

1

1 + 3p(l - p)-’ + (3p + ‘2npX1- p)-’

(8.38)

The results of this section remain valid when holes are moderately

FIG.62. Mixture of circular holes and randomly oriented cracks. Effective Young’s modulus as a function of crack density at different levels of porosity.

Elastic Solids with Many Cracks and Related Problems

43 5

FIG. 63. Mixture of circular holes and parallel cracks. Effective Young’s modulus as a function of crack density at different levels of porosity.

noncircular and randomly oriented (then they can be approximately replaced by circles of equal areas). Results for a mixture of noninteracting holes and cracks are obtained by omitting the factor of (1 - p)- in the formulas (8.35) to (8.38). A n interesting issue is whether the anisotropy due to preferential crack orientations is enhanced or weakened by the background porosity p . The anisotropy is affected by p through two competing mechanisms: (1) in the absence of interactions, porosity reduces the anisotropy; (2) interactions, generally, enhance the impact of cracks; in particular, they enhance the anisotropy. The result (8.37) shows that d(E,/E,)/dp 0, i.e., the first mechanism is dominant: porosity weakens the crack-induced anisotropy.

=-

436

Mark Kachanov

E. NONEQUIVALENCE OF THE APPROXIMATIONS OF NONINTERACTING HOLES AND OF SMALL DENSITY OF HOLES These two approximations are often considered as equivalent, and their names are used as synonyms. In fact, they are not, generally, equivalent. In the approximation of noninteracting holes, equating fo + Af to the potential f of the effective medium yields the following structure for the effective modulus S (denoting either the shear, or Young’s, or bulk modulus; So refers to the matrix without holes):

s/so= ( 1 + c)-’

(8.39)

where p is the appropriate measure of density of holes and C is some constant (formulas (8.16) to (8.18) are examples of the structure (8.39)). Linearization of (8.39) yields the approximation of small density (“dilute 1im it” )

s/so= 1 - cp

(8.40)

(We note that (8.40) coincides, formally, with the approximation of the self-consistent scheme). For circular holes, results in the form (8.40) were given by Vavakin and Salganik (1975) and Day et a/. (1992). There seems to be no need to linearize (8.39). Such a linearization narrows the range of applicability of the approximation of noninteracting holes. (In the case of cracks, the approximation (8.39) remains accurate at high crack densities, see Section VI; the linearization renders this approximation inapplicable at relatively small crack densities). Thus, the linearized “dilute limit” appears to be an unnecessary construction. In the case with nonrandom mutual positions, the approximation of noninteracting defects and the linearized (“dilute limit”) approximation become entirely unrelated. For example, a crack array of an infinitesimally small density can be constructed, such that the interactions are very strong (so that the approximation of noninteracting cracks is therefore inapplicable) and the effective stiffness is reduced to zero (Section V1.K).

F. COMPARISON WITH THE SELF-CONSISTENT AND THE DIFFERENTIAL SCHEMES The self-consistent scheme (SCS) and the differential scheme (DS) place a representative hole into the effective matrix (rather than the effective stress, as in Mori-Tanaka’s scheme); see Section V1.H for discussion. The results are obtained from the approximation of noninteracting holes in a

Elastic Solids with Many Cracks and Related Problems

437

straightforward way, similar to the derivations for cracks. (We ignore the adjustment of the hole density parameter due to the finite probability of “overlapping” of holes that was used by McLaughlin (1977) and Zimmerman (1991b), since consideration of “overlapping” holes is not, in our opinion, fully compatible with the basic assumption that the representative defect is an elliptical hole.) For illustration, we analyze the case of randomly oriented holes (isotropic effective properties) and consider the effective Young’s modulus. Then, instead of (8.20a) for the approximation of noninteracting holes and (8.29a) for Mori-Tanaka’s scheme, we have

E/E,

=

1 - 3 p - q (SCS)

and

E/E,

=

e-(3p+q)(DS) (8.41)

For circular holes, the predictions of DS and of Mori-Tanaka’s scheme are close, but, as the eccentricity g increases, they become increasingly divergent. In the case of cracks, they are quite different (see Figs. 5 2 and 53). As discussed in Section VI.H, the method of Mori-Tanaka (MT) appears to be more physically consistent than the other approximate schemes for interacting defects. In the case of cracks, the MT results (coinciding with the approximation of noninteracting cracks) are confirmed by computer experiments (Figs. 5 2 and 53). Generally, the MT approximation can be shown to follow from a more sophisticated method of effective field that explicitly takes into account the statistics of mutual positions of defects, in the case when these mutual positions are random (Kanaun, 1992). It appears, therefore, that the DS, and, particularly, the SCS, may overestimate the effective com pliance.

Acknowledgments The author is grateful to A. Chudnovsky for the original motivation of the work and discussions and to S. Kanaun, F. Lehner, I. Tsukrov, and C. Mauge for a number of useful remarks. The author is also grateful to C. Mauge for substantial computational help and to I. Tsukrov and B. Shafiro for help in preparation of the manuscript. This work summarizes the research supported, at various times, by the U.S. Department of Energy, the U.S. Army Research Office and the Air Force Office for Scientific Research. Access to the Cornell Supercomputer Facility is acknowledged. Finally, the author is grateful to Victoria Jennings, Academic Press, for her patience and cooperation.

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Author Index

A

Benveniste, Y., 296, 313. 349. 397-399.422. 43 1,438 Beran, M. J., 296,313,349,438 Bergan, P.G., 120,188 Bert, C. W., 68,185 Berthaud, Y.,443 Berveiller, M., 219,222,227,230, 235,255 Betten, J., 369,418,438 Bhat, S. U., 115, 133,186 Biezeno, C. B., 170,186 Bishop: J. F., 210,255 Blakeslee, A. E., 30.65 Boas, W., 192,258 Bodner. S. R., 170,186 Bonar, J. M., 47,54,65 Boltega, W. J., 169, 186 Bower, A. F,, 63, 66 Brace, W. F., 424,445 Bristow, J. R., 347,353,438 Brockenbrough, J. R., 323,344,392,442 Broussard, D. E., 95, 106,186 Bruce, V.G., 170,187 B ~ l lM. , A,, 374, 392,408,440 Bruner, W. M., 393,438 Brush, D. 0..109, 158,186,188 Bucciarelli, L. L.. 158, 169, 186, 188 Budiansky, B., 12,64,212,55,347,35 1,381, 391-393,396,438,443 Buescher, C., 47.54.65 Bullough, R., 1I. 26,42,47, 66 Buresch, F. E., 323,438 Burhns, 0.T., 237,257

Abeyaratne, R., 184,185 Aboudi, J., 397-398,438 Adkins, J. E., 80,84,186 Aifantis, E. C., 195,255 Alexander, H., 31,58,64,78,185 Aliabadi, M. H., 282,438 Allen, D. H., 368,438,442 Almroth, B. 0.. 109,186 Alturi, S. N., 282,443 Aly-Helal, N. A,, 115,186 Anderson, T. L., 282,438 Andreikiv, A. E., 438 Ang, D. D., 394,438 Aravas, N., 195,255 Arikan, E., 1 1 I , 187 Arseculeratne, R., 177, 187 Asaro, R. J., 192-193, 198,211-212,218,223, 235-236,238,240,242-246.248.255 Ast, D. B., 39, 6 I , 64 Atterbuny, T. I., 95,99,188 Attiogbe, E. K., 392,438 Ayers, R. R., 95, 134,186-187

B Babcock,C. D.,99, 103-104, 106, 108, 115, 121, 133-134, 170, 184-185, 186-187 Bahnck, D., 58.65 Baker, G. S., 234,255 Baribeau, J.-M., 6 1 , 6 5 4 6 Bamett, D. M., 15.64.390.439 Basinski, S. J., 192-193,221-222,224,230, 233,250.255-256 Basinski, Z. J., 193,221-222.233, 250,255 Bassani, J. L., 192-194, 199,203,205,209-210, 212-215,218,223,22%231,235-238,240-245, 247,255,257 Bazant, Z. P., 443 Bean, J. C., 3,47,54,57-58,61,6445 Bell, J. F., 222,255

C Cahn, R. W., 219,235,255,257 Cai, M., 390, 398, 438 Calladine, C. R., 99, 133, 168, 186-187 Cammack, D. A., 46.66 Cammarata, R. C., 3 1.64 Cartwright, D. J., 282,444 Chaboche, J. L., 417,442 447

Author Index

448

Chalmers, B., 218, 220, 222, 224,257 Chang, Y.-C., 72,75,78,81,83,85,89,92-93, 119, 134, 138,186-187 Chang, Y. W., 235,247,255 Charalambides. P. G., 323,438,444 Chater, E., 82.93, 115-1 16, 132,186 Chen, T. M., 400,441 Chen, W. T., 394,438 Chen, Y. Z., 28 1,438 Cheung, M. C., 170,186 Chihab, A., 368-369,438,439 Chim, E. S . M., 413,445 Christensen, R. M., 397, 399,438439 Christian, J. W., 198,255 Christoffersen,J., 253,255 Chudnovsky, A,, 281,296,322-323,345,401, 439440,445 Clarke, D. R., 323,439 Clinton, R. I., 213,256 Collins, W. D., 281,283, 300,439 Colwell, J. A,, 149, 186 Cook, N. G. W., 391,442 Cornelison, D. M.. 58-59.66 Comeliussen, A. H., 78,186 Corona, E., 96,186 Costin, L. S., 371,439 Cotterell, B., 274,439 Cottrell, A. H., 219, 235,255 Croll, J. G. A., 115,186 Curtin, W. A,, 344,439

D Dahlgren, V. A,, 391,440 Dalby, R., 46,66 Darwin, D., 392,438 Datsyshin, A., 281,439 Daves, W., 322,440 Davis, R. S . , 218,220,255 Dawson, L. R., 31,65 Day, A. R., 421,436,439 Delameter, W. R., 390,439 Diehl, J., 220, 232,255 Dodson, B. W., 5 8 4 0 , 6 4 , 6 6 Dolgopolsky, A,, 296, 322,439 Dragon, A,, 368-369.438-439 Drucker, D. C., 219,227,258 Dubey, R. N., 94,186 Dundurs, J., 8, 15-16.64-65 Dutta, B. K., 329,439 Dvorak, G. J., 296,313,349,438

Dyau,J. Y., 104, 120, 124, 127, I86

E Eaglesham, D. J., 47,54,61,64-65 Edwards, E. H., 222,234-235.255 El-Bayoumy, L., 158, 169,186 Elam, C. F., 222,235,255 Elyada, D., 121,187 Embury, J. D., 282,323,440 England, A. W., 424,445 Ericksen, J. L., 70,186 Eshelby, J. D., 12, 14.64 Evans, A. G., 323,334,439,444 Ezz, S. S . , 198,203,297,255

F Fabrikant, V. I., 262,271,273,282,292,295, 327,437,439440 Feldman, L. C., 57, 64 Feng, X., 38,47,65 Ferrandon, J., 370,440 Filshtinsky, L. A,, 388, 390,440 Fiory, A. T., 57,64 Fischer, F. D., 322,440 Fitzgerald, E. A., 39.64 Fleischer, R. L., 218,220,255 Folberth, P. J., 149,188 Franciosi, P., 219,222,227,230,235,255 Frank, F. C., 61,64 Freund, L. B., 14,24,26,47,58,63,64-66 Friedrichs, K. O., 179,186 Fritz, I. J., 31, 65 Fu, W. S . , 440 Fu, Y., 323,334,439 Fuh, S., 223,255 Fung, Y. C., 170, I86 Futamura, K., 344,439 G Garboczi, E. J., 421,436,439 Garstone, J., 219-220.255 Gere, J. M., 172,189 Gibbings, C. J., 30.34.58.61.65-66 Gibson, T. L., 95, 106,188 Gjelsvik, A., 170, 186 Gong, S. X.,322-323.440 Gorelik, M., 323,440 Gottesman, T., 374,392,408,440 Gourley, P. L., 31.65

Author Index Gravesteijn, D. J., 61.65 Green, A. E., 80,84,186 Green, Jr., R. E., 222, 255 Greenberg, B. L., 46,66 Greetham, G., 219-220,255 Gross, D., 28 I , 296,440 Groves, S. E., 368,438 G’Sell, C., 115,186 Guggenheim, E. A,, 70,186 Guldenpfennig, J., 213,256

H Hahn, G., 440 Halliwell, M. A. G., 34, 65 Han, L. X., 321, 345,407,440 Hams, C. E., 368,438,442 Hashin, Z., 349, 374, 391-392, 394, 408,440 Haughton, D. M., 78,186 Havner, K. S., 191,212-213,218.223-234.256 Head, A. K., 8.65 Heredia, F., 239, 256 Henmann, G.. 158,189,390,439 Hershey, A. V., 391,440 Hill, R., 191, 194-198,211-212.214, 223, 236237,256,391,422,440 Hirakawa, S., 198,258 Hirota, K., 294,441 Hirsh, P. B., 220-221,256 Hirth, J. P., 14,38,47, 61.65 Hoagland, R. G., 282,323,440 Hodge, P. G., 141,187 Hoenig, A,, 353,440 Hoff. N. J., 170, 187 Holand, I., 120,188 Holthe, K., 120, 188 Honeycombe, R., 219-220,223,255-256 Horii, H., 281,296,322, 376,390,392,398, 400,438,440 Houghton, D. C., 30,34,58,61,6546 Howard, D. J., 3 2 , 4 6 4 7 , 5 5 , 6 6 Huang, Z., 288,441 Hudson, J. A,, 400.441 Hull, R., 47.54.57-58,6445 Humphreys, C. J., 61.64 Hutchinson, J. W., 82,93, 115-1 16, 132, 186-187,211-212,216,218,222,236,253, 255-256,322.323.334,441,444

I Irwin, G. P., 282,444

449

Isida, M., 294,441 Izimi, O., 198, 258

J Jackson, P. J., 222,224,256 Jain, S. C., 11,26,42,47.66 Jensen, H. M., 120,187 Johns, T. G., 99.187-188 Jonas, J. J., 115, 186 Joshi, N. R., 222,256 Ju, G. T., 94, 125, 187 Ju, J. W., 400,419-420,441

K Kachanov, L., 417,441 Kachanov, M., 28 1-283,293-296,298,301, 311, 313, 320, 322,326,328,334, 339,341, 349,354,358,368,369,371,373-376,378, 391,396-397,400,407,417,421,439. 441445 Kakodkar, A,, 329,439 Kamalarasa, S., 99, 133,187 Kamat, S. V., 61.65 Kamel, M., 441 Kamemura, K., 443 Kanatani, K., 441 Kanaun, S., 389,398-399.437.442 Kaplan, A,, 170,186 Kapshyvij, A. A,, 442 Karbhari, V., 322,439 Katsounas, A. T., 120,189 Keer, L. N., 440 Kelly, A,, 192,256 Kemeny, J., 391,442 Kirchner, P. D., 39,61,64 Knowles, J. K., 184,185 Kocks, U. F., 221-222,224,235,256 Koiter, W., 212,256 Kopystyra, N., P., 442 Krancinovic, D., 368,371,413,417,442 Kroner, E., 442 Kuhlmann-Wilsdorf, D., 220,256-257 Kuzmin, Y. N., 442 Kvam, E. P., 61.64 Kwak, S. S., 322,439 Kyriakides, S., 72,75,78,8 1,83,85,89,92-94, 96,99, 102-104, 106, 108, 110-111, 115-116, 119-121, 124-127, 132-134, 138, 147, 150,155, 158, 161,163,165,168,177,180,184,186-189

450

Author Index L

Laflen, J. H., 199,211,258 Laird, C., 205.218-220,223,225-230,235. 256-258 Langner, C. G., 134,187 Laures, J.-P., 282,292-295,298,301, 322,326, 441 -442 Laws, N., 323,344,392,442 Lax, M., 346,398,442 Lebedev, N. N., 442 Leckie, F. A., 371,443 Lee, J. W., 368,442 Lee, M. S., 16,65 LeGoues, F. K., 32,65 Lehner, F., 349,442 Leibenguth, R. E., 58.65 Lekhnitsky, S. G., 355,442 Lemaitre, J., 417,442 Leroy, Y., 247,257 Levin, V., 398,442 Levy, M., 94,188 Li, F. S., 158, 161, 163, 165,188 Liaw, B. M., 441 Lietzau, H. P., 442 Light, T. B., 20,26,29,66 Litewka, A., 368,443 Livingston, J. D., 222,255 Lo, K. H., 397,439 Lochridge, J. C., 95,106,188 Loethe, J., 1 4 1 5 , 6 4 6 5 Lomer, W. M., 221,257 Lowengrub, M., 271,444 Lyons, M. H., 34.65

M Mack, R. D., 149,186 Mader, S., 20,26,29,66 Madhavan, R., 134,185 Maeshibu, T., 368,443 Maher, D. M., 61,64 Maiti, S. K., 329,439 Mandel, J., 192-193, 212,257 Marguerre, K., 170,188 Martin, C. J., 149,186 Martin, J. H., 119, 133. 141, 188 Masur, E. F., 170, 176177, 179, 181,188 Matsubara, N., 149, 158,189 Matthews, J. W., 20,26, 29-31,6566 Mauge, C., 320,341,373-374,407,421,443

Maugin, G. A., 413,417,443 Maurer, K. L., 322,440 McCaig, I. W., 149, 188 McGhie, R. D., 158,188 McLaughlin, R. A., 394,437,443 McMeeking, R. M., 323,438,444 Meguid, S. A,, 323,440 Mehrabadi, M. M., 371,443 Melin, S., 3 1 1,443 Mesloh, R. E., 95.99.187-188 Meyerson, B. S., 32.65 Mimaki, T., 149,188 Mitchell, T. E., 220,257 Miyasaka, A., 149,188 Mohan, R., 229,238,247,257 Montagut, E., 31 1, 313,322,328, 334, 339-340, 344,441,443 Montel, R., 149, 188 Morar, J. F., 32.65 Mori, T, 399,43 1,443 Mroz, Z., 368,439 Murakami, S., 369,418,443 Muskhelishvili, N. I., 9-10.66,423,443

N Nakada, Y., 221,224,235,256 Nakahara, S., 57.64 Neale, K. W., 115,187-188 Needleman, A,, 85,189,237,247,257 Nemet-Nasser, S., 281,296,322,371, 376, 392, 440,443 Nicholson, R. B., 192,256 Nisoshika, T., 282,443 Nix, W. D., 7.34,36,46,58-61,66 Noble, D. B., 34,36,58-61,66 Noguchi, H., 294,441 0 O’Connell, R. J., 347, 351,381,391-393, 396, 438,443 Oda. M., 368-369,371,443 O’Donoghue, P. E., 282,443 Ogawa, H., 149,188 Ogden, R. W., 78,186,188 Ohno, N., 369,418,443 Onat, E. T., 371,443 Ono, S., 198,258 Ortiz, M., 247,257, 323,443

Author Index P Paine, D. C., 32,4647,55,66 Palmer, A. C, 95, 119, 133, 141,188 Panasyuk, V. V., 438 Paris, P. C., 282,444 Pasha, M. L., 443 Peirce, D., 212,257 Perovic, D. D., 6 1 , 6 5 4 6 Peticolas, L. J., 58,65 Petruzzello, J., 46,66 Pettit, G. D., 39, 61, 64 Pian,T.H.H., 158, 169,186,188 Piau, M., 353,443 Picraux, S. T., 58-59,66 Piercy, G. R., 219,235,257 Pijaudier-Cabot, G., 443 Pipkin, A. C., 92,188 Pope, D. P., 198-199,201,203,207,239,297, 255,257 Pozinenko, 9. V., 370,444 Price, R. J., 193,235,257 Proano, R. E., 39.6 I , 64

Q Qin, Q., 192-193, 199,203,205,209-210, 214-215,236-238,240-244,247.257

R Ramaswarni, B., 222,224,257 Ramirez, J. C., 63.66 Raniecki, B., 237,257 Reifsnider, K., 4 16,444 Reissner, E., 108, 158,188 Rernseth, S. N.. 120, I88 Rice, J. R., 12. 15, 22, 59,64,66, 192-194, 198 212,23&238,240,257,274,379,385,439, 444 Roach, D., 104, 116, 132-133,187 Robinson, I. K., 57,64 Romalis, N. B., 323,444 Rornrn, E. S., 370,444 Rooke, D. P., 282,438,444 Rose, L. R. F.. 322,444 Rosenfield, A., 440 Rosi, F. D., 220,257 Rubenstein, A,, 322, 328,444 Rudnicki, J. W., 236237,257 Rudnicky, J. W., 379,444

45 I

Ruhle, M.,323,444

S Sahasakmontri, K., 400,440 Salah, S., 203,257 Salganik, R. L., 349, 388,394,436,445 Sanders, J. L., 120,188 Satake, M., 371,444 Savin, G. N., 423,444 Savruk, M., 281,439 Sayers, C., 381,391,396-397,400,444 Schmid, E., 192,258 Schreyer,H. L., 170, 176-177, 179, 181,188 Seeger, A,, 192,22&22 I , 258 Sen, P. N., 421,444 Sendeckyj, G. P., 16, 64 Sewell, M. J., 253,258 Shalaby, A. H., 218,235,255 Sheh, M. Y., 199,258 Shield, R. T., 78,81,186,188,444 Short, K. T., 58.65 Shu, D., 68,189 Shurn, D., 322,444 Sieradzki, K., 31, 64 Sneddon, I. N., 271,444 Snyder, K.A,, 421,436,439 Sokolowski, M., 322,445 Song, H.-W., 120, 184.189 Sorenson, J. E., 95,99,187-188 Spence, J., 99, 106, 115,189 Steel, W. J. M., 99, 106, 115,189 Stinchcomb, W., 416,444 Stoffel, N. G., 32,4647.55.66 Stonge, W. J., 68, 189 Stouffer, D. E., 199,21I , 258 Suemasu, H., 413,445 Suresh, S., 321, 345,401,440 Suzuki, K., 368,443

T Tada, H., 282,444 Takasugi, T., 198,258 Talreja, R., 371, 315,444 Tamuzh, V. P., 323,444 Tanaka, K., 399.43 I , 443 Tandon, G. P., 422,431,444 Tassoulas, J. L., 120, 184.189 Taylor, G. I., 192,210,212,218,222,258 Texter, H. G., 148-149.189

452

Author Index

Thornton, P. R., 220,257 Thorpe, M. F., 421,436,439,444 Thouless, M. D., 43,66 Timoshenko, S., 110, 170, 172,189 Tsao, J. Y., 58-60.64,66 Tseng, K. H.,400,441 Tsien, H . S . , 179,189 Tugcu, P., 115,188 Tuppen, C. G.. 30,34,58,61,6546 Turlo, J. F., 34.36, 58-61,66 Turska-Klebek, E., 322,445 Tvergaard, V., 85,189

U Uflyand, Y. S., 295,442,445 Ullman, F., 149,189 Untenvald, F. C., 58.65

V Vakulenko, A,, 354, 368.445 van de Walle, G. F. A., 61, 65 van der Berg, N. G., 26.66 van der Merwe, J. H.. 26, 39,64,66 van Gorkum, A. A,, 61,65 van Ijzendoom, L. J., 61.65 Van Stone, R. H., 199,211,258 Varadarajan, R., 2 13,255 Vause, R. F., 234,256 Vavakin, A. S., 349,388,394,436,445 Vitek, V., 198,203,297,255 Vriezema, C. J., 61.65 W

Walker, G. E., 95,186 Walpole, L. J., 445 Walsh, J. B., 347, 353, 376,422,424,445 Wang, S. S., 413,445

Washbum, W., 222,236235,255 Watanabe, S., 198,258 Watson, G. P.,39,61,64 Weatherly, G. C., 6 1 , 6 5 4 6 Weng, G. J., 42 1422.43 1,432,444445 Werder, D. J., 58,65 Wierzbicki, T., 115, 133,186, 189 Williams, M. L., 394,438 Williams, R., 199.21 1,258 Willis, J. R., 11, 26, 42, 47, 66, 402,408,445 Willmore, T. J., 283,445 Wittke, W., 370,445 Woodall, J. M., 39, 61. 64 Wu, S., 323, 345,401,439,445 Wu, T., 193,229,258 Wu, T. T., 219,227,258 Wu, Tien-Yue, 192,205,218,223,225-226, 228,230,235,258 Wung, E. C. J., 296,313,349,438

Y Yarnabe, T., 443 Yamamoto, Y., 149, 158,189 Yeh, M.-K., 103, 106, 108. 110, 116, 126, 132-133,187,189 Yin, W.-L., 92,189 Yoshida, T.. 294,441 Youn, S. K., 158, 161, 163,187 Z

Zagustin, E. A., 158, I89 Zalm. P. C., 6 1.65 Zaoui, A,, 219,222,221,230,235,255 Zarka, J., 227,258 Zarzour, J., 296,313,349,438 Zhao, Y. H., 421,432,445 Zimmerman, R. W., 390,422,424,445

Subject Index

A

pressure of tubes, 94, 121, 125 Bimetallic pipe, see Cladded pipe Blocking criterion, 52 Blocking dislocation, 47 Bounding effective moduli, 401-402.408410 Buckle arrestor, 95, 106 Buckling pressure of arches, 172 of elastic-plastic tubes, 125 of elastic tubes, 94 of panels, 180 Burgers displacement, 9 Buried strained layer, 36

Activation energy, dislocation glide, 58 a-type tensor, 370 Alternative crack density parameter, 41 1 4 1 2 Anisotropic matrix crack arrays, computer experiments, 4 0 7 4 0 8 crack interaction, 320-321 crack-microcrack, 338 noninteracting cracks, 372-376 Anisotropy, stress-induced, 380 Antiplane forces, 268 Antiplane loading, 263 Approximation of noninteracting cracks, 352-353, 389,399 randomly oriented cracks, 404,406 Approximation of noninteracting holes comparison with self-consistent and differential schemes, 43&437 nonequivalence with approximation of small density of holes, 436 Approximation of small crack density, 352 Approximation of small transmission factors, 297-299 Approximation of widely spaced cracks, 299-301 Arch high, 172 shallow, 171 symmetric buckling of, 172 unsymmetric buckling of, 172, 174, 176 Aspect ratio, 3 16

C Capping layer, 34 Casing, 94, 147-148 Circular cracks arbitrary 3-D array infinite solid, 291-293 cracked solids, 357-362 Cladded pipe, 147,149 Coarse slip band, 192,235,246,248-250 COD tensor cracked solids, 350-351 crack in anisotropic solid, 372-373 infinite isotropic solid, 35 1-352 Collapse configurations of confined shells, 154,160, 163 of tube, 129 Collapse of confined shells under pressure, uniform (axially) analysis of, 156 Collapse of tubes under external pressure analysis, 108 first yield criterion, 110 uniform, 108 uniform discrete models, 117 Collapse pressure of tubes, 94, 10&107 Collinear cracks, 301-302 interaction analysis, 283-286

B Battelle Laboratories, 95 Bauschinger effect, 229 Bicrystal, 1, 14 elastic constants, 15 mismatch strain, 5 Bifurcation buckling check for uniformly inflated tubes, 81 pressure of arches, 172 453

454

Subject Index

periodic row, interacting, 3 19-320 zone of influence, 307 Complimentary energy density, 426 Confined cylindrical shells buckling of, 149 localization in, 15 1 propagating buckles in, 149, 151-154 Coplanar crack, zone of influence, 307-308 Core, dislocation, 28 Core cutoff radius, 1 1 Crack clustering of, 415 elliptical, 366-367 interacting with circular holes, 433-435 lubricated, 376-378 noninteracting, 352-372 alternative crack density parameter, 41 1 in anisotropic matrix, 372-376 characterization by vectors, 37 1-372 character of orthotropy, 362-363 constrained against opening, 376-380 crack density tensor, 368-371 disturbances of orientational randomness, 363-365 drained and undrained conditions, 385 elastic potential, 383-386 filled with compressible fluid, 380-385 fluid pressure polarization, 385 noncircular cracks, 366-367 plane problem, 365 sliding with friction, 378-380 sliding without friction, 376-378 3-D case, 357-362 2-D case, 354-357 parallel, high density, model, 401 random arrays, microcracking and elastic moduli change, 414 rectilinear front, 325-328 Crack array, arbitrary 2-D, infinite plate, 286-288 Crack density, second order, models, 400401 Crack density parameter, 347,41041 1 alternative. 41 1 4 1 2 Crack density tensor, 353-355 applications to physical properties, 369-37 1 families of parallel cracks, 357 parallel cracks, 360-361 self-consistent scheme in tenns of, 393-394 in terms of invariants, 368-369 Cracked solids, effectiveelastic properties, 345-412 alternative crack density parameter. 41 1-412 approximate schemes, 389402

average strains and stresses, 348-350 bounding effective moduli, 401402,408-410 characterization by vectors, 371-372 character of orthotropy, 362-363 circular cracks, 357-362 COD tensor, 350-351 computer experiments on crack arrays in anisotropic matrix, 407-408 deterministic arrays, 402-407 crack density tensor, 353-355,368-369 crack orientation statistics, 361-362 cracks parallel to axes of orthotropy, 373-374 differential scheme, 394-396 dimensionality effect, 366 effective matrix methods, 391 modifications, 398 effective moduli, interaction impact, 386-389 elastic potential, 350, 368-369 generalized self-consistent scheme, 397-398 infinite isotropic solid, COD tensor, 35 1-352 isotropic orientation distribution, 356-357, 359-360 loading path dependence, 378 method of an effective field, 398-399 Mori-Tanaka’s method, 399-400 naturally occumng crack arrays, 407 noncircular cracks, 366-367 noncoaxiality of physical properties, 37 1 noninteracting cracks, 352-372 constrained against opening, 376-380 filled with compressible fluid, 380-385 in anisotropic matrix, 372-376 parallel cracks, 360-361 path independence, 378-379 plane problem, 365 preservation of orthotropy for interacting cracks, 406 self-consistent scheme, 391-394 sliding with friction, 378-380 without friction, 376-378 solids with cracks versus inclusions, 346-347 terms of invariants, 375-376 two families of parallel cracks, 357 uniaxial compliance, 377 Crack interaction matrix, 288 Crack interactions, 271,301-321 analysis, 283-296 accuracy, 293-295 arbitrary 3-D array of circular cracks, infinite solid, 291-293

Subject Index arbitrary 2-D crack array, infinite plate, 286-288 collinear cracks, 283-286 comparison with polynomial approximation techniques, 295-296 full stress field construction, 288-290 in anisotropic matrix, 320-321 cracks filled with compressible fluid, 315-320 interacting cracks, 3 18-320 one isolated crack, 316-317 crack touching line of another crack, 3 13 with field of microcracks, 32 1-345 asymptotic 2-D case, 322-323 crack-microcrack configurations, 333-334 equations, 324-329 interaction effect fluctuation, 342 large microcrack arrays, 323,333-343 macrocrack interactions, 329-33 1 microcrack in wake zone, 332 modelling by effective elastic, 344 primary and secondary modes, 338 rotated microcrack interactions, 33 1-332 short- and long-range interactions, 336,338 toughening by microcracking, 344-345 fluid impact, 3 19 isolated fluid-filled crack, 320 range of influence of crack in an array, 3 6 3 0 8 relative strength of interaction effects, 303-305 slightly asymmetric arrays, extremal properties, 308-3 1 1 stress shielding and amplification, 301-306 3-D configurations, 305-306, 314-3 15 2-D configurations, 31 1-313 Crack-microcrack configuration asymmetric, 333-334 coplanar, 333 Crack-microcrack interaction, 4 16 in anisotropic matrix, 341 equations, 324-329 accuracy, 328-329 3-D configuration, 325-328 2-D configuration, 324-325 Crack opening displacements circular crack loaded by uniform traction, 274-275 collinearity, 270 from pair of point forces, 269 relation with traction, 270-271 shear, 378 uniform loading, 269-270 Crack tip fields, elastic solids, 279-280

455

Creep, 418 Critical thickness, 20, 28 buried layer, 36 with capping layer, 32 energy criterion, 20,26 equilibrium criterion, 20,26 superlattice, 38 Cross slip effect, 201-205 Crystal critical resolved shear stress, 198 cross slip effect, 201 elasticity, 196-197 flow, 211-217 nonassociative. 212 normality structure, 2 12 slip rate, 21 1 uniqueness, 214-2 15 kinematics, 194 non-Schmid effect, 198-199.201 shear stress, 2OC-201 yield behavior, 198-21 1 plasticity, 194-216 Schmid law, 299,203 Schmid stress, generalized, 196-200 plastic-work-rate conjugate, 197 slip vector, 194,20&201 spherical triangle, 202.206-207,216,231 yield criteria, 199-208 potentially active, inactive, 198-199 yield surface, 208-21 1 vertex effect, 210,240 Cubic materials, 29 Curvature, film, 6 Cyclic deformation, 229-230

D Damage parameters adjustable, 420 choice, 418-419 Darcy’s law, 370 Differential scheme, 394-396 comparison with approximation,4 3 W 3 7 extension, 396-397 Dislocation forest, 221 Hirth lock, 228 interaction, 220 junction, 227-228 coplanar, 228 glissile, 228

Subject Index

456

sessile, 228 Lomer-Cottrel lock, 221 pile-up, 221 Dissociation, dislocation, 3 1 Driving force, threading dislocation, 23 Dynamic propagation of buckles in tubes, 184 of instabilities, 184

E Eccentricity parameter, 428 Eccentricity tensor, 428 Edge dislocation isolated, 9 periodic array, 11 Effective elastic material, microcracked zone modelling, 344 Elasticity, 196 Cauchy stress, 196197 Kirchhoff stress, 196 second Piola Kirchhoff stress, 196 Elastic mismatch strain, 5 nonuniform, 32 Elastic moduli, change and micmracking, 413417 Elastic potential, 354 cracked solids, 350 damage parameter choice, 418-419 effective properties and, 417418 noninteracting cracks, 383-384 noninteracting elliptical holes, 4 2 7 4 3 1 in strains, 419420 structure, 421 in terms of invariants, 368-369 Elastic properties, see atso Solids, with elliptical holes effective, elastic potentials and, 417418 Elastic solids, linear, 259-437 crack opening displacements,269-270 many cracks, 280-301 arbitrary arrays, 282 crack interaction analysis, see Crack interactions Schwarz-Neumann alternating method, 282 small transmission factor approximation, 297-299 widely spaced crack approximation, 29S301 nonuniformly loaded crack, 270-27 1 one crack, 26 1-280 crack tip fields, 279-280 energy release rate along crack edge, 273

far-field asymptotics, 275-279 stresses from uniform tractions, 27 1-273 three-dimensionalfields, 27 1-275 stress intensity factors, 268-269,273-274 stress fields, 262-268 two-dimensional fields, 262-27 1 Electric conductivity, crack density tensor applications, 37 1 Elliptical holes, see Solids, with elliptical holes Energy, release rate along crack edge, 274 Energy buckling load. 179 Epitaxy, 2 Excess shear stress. 58

F Far-field asymptotics, 282-283 elastic solids, 275-279 Flow, see Plastic flow Flow stress ratio, 234 Fluid compressible, in cracks, 315-320 pressure polarization, 385 Fluid filtration, crack density tensor application, 369-370 Fluid pressures, coupling with stress interactions, 3 18-320 Force on dislocation, 4 driving force, 4 image force, 4

G GaAs/Si film, 2 Generalized force, 25,63 Glide surface, 21 Green’s tensor of elasticity, second, 288

H Hardening, 212,217-235,249,252 analytical characterization,226-230 backward extrapolation, 223 Bauschinger effect, 229 cyclic deformation, 229-230 easy glide, 22 1 experiments, 221-225 inequality restriction, 225 interaction factor, 227-228 isotropic, 212 kinematic, 212 latent, 212

Subejct Index multiple slip, 226-230, 244 observations, 21 9-225 orientation dependence, 218-219.232 stage I, 11,111. 22&221, 227-229 Taylor's law, 216 tension/compression asymmetry, 21 5-217 Hole compliance tensor, 426

457

superpartial, 204 tension-compression asymmetry, 2 16 Localization in a panel, 174-175 in collapsing tube, 123, 127 in inflated tube, 85 of instability, 182-183

I Inflation of elastic tubes, 70. 77 localized, 74 uniform, 70,78,80 InGaAs/GaAs film, 2.39 Initial imperfections, 109, 126, 158, 161 Initiation of buckles in confined shells, 151, 153 of buckles in panels, 174-175 of buckles in tubes, 96-97 of bulges in tubes, 70 of collapse in tubes, 119, 121 of propagating buckles in pipeline, 96-97 of propagating instabilities, 182 Initiation pressure of propagating buckles in confined shells, 153 of propagating buckles in panels, 173-174 of propagating buckles in tubes, 94, 102 of propagating bulges in tubes, 7 1.75 of propagating instabilities, 182 Installation, offshore pipeline, 96 Isotropic solid, infinite, COD tensor, 35 1-352

K Kinematics, 194 elastic, plastic, 194-196 intermediated configuration, 195 Kinetics, dislocation glide, 56

L Latent hardening ratio, 234 Ledge, surface, 3 1 Limit load instability, 81,85, 114, 122, 161, 164, 169. 182 Limit pressure of confined shells, 162 L12 intermetallic compound, 203-208, 215-217 cross slip, 204 multiple slip, 216,219 non-Schmid stress, 203-2 I 1 PPV theory, 203 Shockley partial, 204

M Macrocrack interactions with collinear microcrack, 329 with parallel microcracks, 329-33 1 modelling, 326 Macroscopic shear bands, 192,235,243,25&252 Maxwell construction for propagation of buckles in confined shells, 165 of buckles in panels, 178 of buckles in tubes, 116, 1 18-1 19 of bulges in tubes, 83 of instabilities, 184 Membrane axisymmetric, 83-84 circular cylindrical, 78 Metastable state, 57 Method of an effective field, 398-399 Microcrack, see also Crack interactions clusters, 340-341 collinear, interaction with macrocrack, 329 interaction effect fluctuation, 338 large array, interaction with crack, 323,333-341 nonuniform density, 339 parallel, interaction with macrocrack, 329-331 resistance to fracture propagation, 322 rotated, interaction with main crack, 331-332 damage parameter, 418 wake region impact, 339-340 in wake zone, 332 zone shape, 334-335 Microcracking change of elastic moduli and, 4 1 3 4 1 7 toughening by, 344-345 M-integral, 12 Misfit dislocation, 5 parallel array, 39 sequential formation, 43 simultaneous formation, 41 Mori-Tanaka model, 43 1 Mori-Tanaka's method, 3 9 9 4 0 0

45 8

Subject Index N

experimental procedure, 72 numerical simulation, 85-87 Ni3AI under tension, 77, 79,91 tension, compression, 207 Propagating buckles in panels, 169-181 uniaxial stress-strain curve, 217 expenmental demonstration, 173-1 75 yield loci, 209 Propagating buckles in tubes and pipes, 94-147 Non-Schmid stress, 198-21 1,238-247 effect of, in pipeline design, 106 Nucleation, dislocation, 31, 61 experimental procedure, 10&101 heterogeneous, 61 numerical simulation, 128, I30 homogeneous, 61 Propagating buckles in tubes under tension, 134-144 0 experimental procedure, 135- 137 numerical stimulation, 143 Offshore pipelines, 94 predictions of propagation pressure, 141-144 design of, 106 propagation pressures, 138-14 1 propagating buckles in, 69 Propagating instability, 68, 183 Oil can effect, defined, 172 Propagation pressure of buckles in confiied shells definition, 154 P experimental determination, 153 Panels, shallow, 172-181 experimental values (elastic-plastic shells), buckling, 174 155-1 57 localization in, 175 experimental values (elastic shells), 155 propagating buckles in, 174175 predicted values (elastic shells), 165-166 Peach-Koehler force, 24,49 Propagation pressure of buckles in panels Peierls-Nabarro stress, 3 1 definition, 174 Phase transitions experimental determination, 173 in liquid-vapor fluids, 83 predicted values, 179 in solids, 70. 184 Propagation pressure of buckles in tubes Plastic flow, 211-217, 230-235 definition, 95, 101 L12 intermetallic compound, 215 experimental determination, 99 localized, 235-237 experimental values, 104105, 107, 131 slip system, 21 1 Palmer-Martin estimate, 119 uniqueness. 214 predicted values (numerical simulation), 128, Poisson’s ratio, effect of crack density tensor, 360 130-131 Pressure-time history predicted values (uniform collapse), 115-1 19 of confined buckled propagation experiment, 153 Propagation pressure of buckles in tubes under of tube collapse and buckle propagation tension experiment, 101 definition, 137 of tube inflation experiment, 74 experimental determination, 137 Profile of experimental values, 138-140 confined propagating buckle, 155 predicted values (numerical simulation), 143-144 propagating buckle in panel, 175 predicted values (uniform collapse), 141 propagating buckle in tube, 102, 144 Propagation pressure of bulges in tubes, 75, 87, propagating bulge in tube, 79,92-93 definition, 7 I Propagating buckles in confined shells, 147-169 experimental determination, 72, 75-78 definition, 147 experimental values, 79 elastic, 150 predicted values (numerical simulation), 87 elastic-plastic, 151 predicted values (uniform inflation), 79.82, 87 experimental procedure, 150-154 R uniform collapse analysis, 156 Propagating buckles in inflated tubes, 70-93 Riser, 94

Subject Index S

Saint-Venant’s relations, 355,428 Schwarz-Neumann alternating method, 282 Screw dislocation, 12 periodic array, 12 Self-consistent scheme, 39 1-394 extension, 396397 formulation in terms of crack density tensor, 393-394 generalized, 397-398 2-D, 392 Shear band, 235-254 coarse, 248-250 conjugate, system, 247, 25 1 crystallographic, 235 first bifurcation, 249 primary, secondary, system, 247-248,251 secondary slip, 236,248 single slip, 236, 248 macroscopic, 25@2-54 double-slip, 250 noncrystallographic, 235 Shear forces, 268 Shear loading, 262-263 Shell liner, 148 SiGe/Si film, 2, 30,47,54,58 Slip double cross, 221 planar model, 24G242 multiple, 226 orientation, 250 overshoot, 222 primary, conjugate system, 247 single, 23 1-234,238,249 Solids, see also Cracked solids with cracks versus with inclusions, 346-347 with elliptical holes, effective elastic properties, 421-437 interacting elliptical holes, 43 1 4 3 3 interacting circular holes and cracks, 433435 noninteracting elliptical holes, 4 2 7 4 3 1 one elliptical hole in uniform stress field, 422-427 parameters of density of holes, 42 1 Spacing, dislocation, 40.46 Stacked configurations, 302 Starlike configuration, 312-3 13 Stiffness reduction effect, asymmetry, 374

459

Strain in cracked solids, 348-350 elastic potential in, 4 1 W 2 0 volumetric, due to hole, 425 Strained-layer epitaxy, 3 Strain energy density function incompressible material, 79 of Ogden, 78 Strain localization, 235-254 constitutive, geometric instability, 236 multislip hardening, 244 non-Schmid effect, 238-247 planar double slip model, 240 nonsymmetric, 243 symmetric, 242 post-bifurcation, 245 secondary slip, 238,247 shear bifurcations, 237 single slip, 238 3-D calculation, 247 coarse slip bands, 248-250 double slip orientation, 250 elasticity, effect, 247 macroscopic shear band, 25C-254 single slip orientation, 248 vertex effect, 240 Stresses, in cracked solids, 348-350 Stress fields, 262-266 in microcracked zone, 324 one elliptical hole in, 422-427 Stress intensity factors, 268-269.273-274 Stress interactions, coupling with fluid pressures, 3 18-320 Surface energy, 31

T Tensionlcompression asymmetry, 198,206-208, 2 15-2 17 Threading dislocation, 3, 5, 19 applied stress, 20 driving force, 23 self stress, 20 sequential formation, 43 simultaneous formation, 41 Toughening, by microcracking, 344-345 Transmission factor, 285

U Uniqueness. 214-2 15

460

Subject Index

Up-down-up local response, 81, 114, 164, 170, 183-184

V Vegard’s law, 7 Volume controlled collapse of shells, 128 experiments, 72, 101 inflation, 72 pressurization, 70.99, 153

cross-slip effect, 201-203 L12 intermetallic compound, 201-21 1 non-Schmid stress, 199 Yield locus, surface, 209 Yield moment, 141 Yield pressure, 112 Yield tension, 138 Yield vertex, 252 Young’s modulus, 3 9 6 3 9 7 as function of crack density, 4 3 3 4 3 5 parallel cracks, 4 0 3 4 0 5 randomly oriented cracks, 4 0 3 4 0 5

W Z

Wet buckle, 104

Y Yield criterion, 199-21 1

ZnSelGaAs film, 2 . 4 6

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ISBN 0-12-002030-0 90051

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