Role of coatings in axial tensile strength of long fibre-reinforced metal-matrix composites

Acta metall, mater. Vol. 41, No. 7, pp. 2097-2104, 1993

0956-7151/93 $6.00 + 0.00 Copyright ,~ 1993 Pergamon Press Ltd

Printed in Great Britain. All rights reserved

ROLE OF COATINGS IN AXIAL TENSILE STRENGTH OF LONG FIBRE-REINFORCED METAL-MATRIX COMPOSITES Z H E N H A I XIA Department of Metallic Materials Science and Engineering, Hebei Institute of Technology, Tianjin 300130, P.R. China (Received 15 May 1992; in revised form 22 December 1992)

Abstraet--A model that includes effects of coatings, interfacial behavior, plastic deformation of matrix and reaction zone has been developed for analysis of the behavior of metal-matrix composites reinforced by coated fibres. The stress concentration caused by the cracks in the reaction zone was calculated from the model and the results show that it can be relaxed by choosing coatings of low modulus and controlling interfacial strength to a relatively low value. The predictions of the model in composite strength are consistent with that from the Griffith relationship with strong interfacial bonding and the experimental results for SiC-coated C/AI composites. Both the theory and the experiment show that high strength of the composites can be maintained by SiC coating even when there is a serious reaction at the coating/matrix interface. Zusammenfassung--Ein Modell, das die Einfl~sse der Schichten, das Grenzflfichenverhaltes, Reaktionzone und der plastischen Verhindern der Matrix behandelt, wird ffir die Mechanischenverbalten-Analysen der Metall-Matrix-Verbundwerkstoffen mit den geschlichteten Fasern beschrieben. Die Spannungskonzentrationen in den Fasern, die Risse in der Reaktionzone geherbeifuhrt, wurden berechnet, und die Ergebnisse zeigen, dal3, er wird mit den Schichten niedrigen Moduls und den Faser/Schichte-Grenzfl/ichen relativen niedrigen Festigkeit erchlafft. Die Voraussagen des Modells in der Festigkeit der Verbundwerkstoffen sind konsequent mit Griffith-Relation in der Beschaffenheit der festen Grenfl/ichenfestigkeit und dem experimentellen Material von Aluminium-Matrix-Verbundwerkstoffen mit Siliziumkarbidgeschlichten Kohlefasern.

1. INTRODUCTION M o s t metal-matrix composites are non-equilibrium systems. During fabrication and service of the composites at high temperature, chemical reaction usually occurs at the fibre/matrix interface, resulting in property degradation. The chief reason for the degradation is the formation of microcracks in reaction zones which lead to the premature failure of the fibres during loading. The strength of the composites as a function of the thickness of the reaction zones was well predicted by Ochiai [1] and Metcalfe [2]. The problem of interphase reactions and accompanying property degradation can be rectified by introducing coatings that can reduce the growth of reactions between the fibre and the matrix. In addition to serving as diffusion barriers, an important role played by the coatings would be to arrest the impinging cracks and contain the damage [3, 4]. In most coatings of current interest, the reaction zone is still formed at the coating/matrix interface due to diffusion through the coatings and/or the reactions between the matrix and the coating. Nevertheless, by means of the crack-arresting characteristic of the coatings, it is possible to prevent the cracks from the partially

reacted outer layer into the fibres by proper choice of the coatings and control of the strength of the interface between the fibres and the coatings. However, analysis of the effects of the coatings, interfacial behavior and reaction zone is made difficult by the lack of the methods. In the present paper a model has been proposed for analyzing the behavior of composites reinforced by the coated fibres. Effects of the coatings, interfacial behavior, matrix yielding and reaction zone on the stress concentrations and strength of the composites are predicted. Comparisons are made between the results from the model and the Griffith relationship and the experimental data on SiC-coated C/A1 composites to examine the validity of the model. 2. DEVELOPMENT OF THE MODEL We consider a composite consisting of a volume fraction Vf of uniformly-distributed and aligned fibres coated with a coating of thickness h and a reaction zone of thickness R at the matrix/coating interface. The composite is assumed to be composed of aligned cylinders in which a central core of the coated fibre is surrounded by a reaction zone and a

2097

2098

ZHENHAI XIA: ROLE OF COATINGS IN METAL-MATRIX COMPOSITES shear stress in coating is assumed to be constant and equal to zs. In the stage of elastic shear deformation of the matrix, its shear stress is given by Xm = Mm Y

(2)

and in the stage of plastic shear deformation it is given by "rm= flMmy + (1 -- fl)Zy

Ring crack

\

Matrix yielding

zone Fig. I. Schematic representation of the model, a unity cylinder in the composites, consisting of a core of coatcd fibre, reaction zone and outer matrix layer.

where fl is the slope of the shear strain stress-strain curve in plastic deformation, normalized with respect to Mm. The coating deforms only elasticly in shear before fracture. Noting the displacements of the fibre Uf and the reaction layer Ur, the shear stresses of the coating and matrix are given by Zc = (U r --

uf)nc/h

"rm=CUr--~ffx)Mm/~ matrix layer, as shown schematically in Fig. 1. The thickness of the matrix layer is given by df ]/2 _ 1) -- h. 6 = ~-(v?

(1)

W e assume that thcrc is a ring crack in the reaction zone. As the cylinder is subjcct to an overall stress to the cylindrical axis, the crack would result in stress concentrations depending on the thickness of thc reaction zone, propcrties of the coating and matrix, and intcrfacial bonding strength. W c assumc that shear stresses in the fibre and rcaction zone can be neglected and the matrix and coating play a role only as the strcss-transfcr media. With this ncglcction, thc displacements of thc fibre and reaction laycr could be given as a function only of x [5], the axial coordinate parallel to the fibre. The effect of thermal residual stress is also neglcctcd in the analysis. Because of largc clastic shear stress concentrations in the matrix and the coating at thc root of the crack and relatively weak interracial strength and matrix strength of most compositc materials we anticipate that thcrc will be nonelastic effects such as interracial debonding and plastic dcformation in the matrix at the root of the crack. W c therefore include in the model three regions: Region A where intcrfacial debonding occurs and the shear stress in thc matrix is higher than its shear yicld strcngth, Region C whcrc neither interracial debonding nor plastic deformation of the matrix occurs, and Rcgion B where there arc two cases: one (Casc I) that intcrfacial dcbonding occurs but the matrix does not yield and thc other (Case II) that the matrix yields but no dcbonding occurs. Noting that axial dimensions of the interracial debonding and matrix yielding zones as a and b, respectively, Region A covers the region of 0 ~< x ~< a (a < b) or 0 ~< x ~< b (a > b), Region B thc region of a <~x <~b(a < b) or b <~x <~a(a > b)and Region C

the region of b ~ b). In regions where the interfacial debonding occurs, the

(3)

(4) (~'m~ "Cy)

(5)

f o ~ ) Mm~/~+(l--~)~, (~m>~,) (6) ~m; ( -U,---~x and the stress concentration factor for the fibre are given by N =dUf dx '

(7)

Combining (1)-(6), we have the equations of equilibrium as follows: For Region A S _ d2Ur f/$f

.

" ~ -1-/taf'~s =

0

(8)

d2Ur

SrEr"~x2-- ~(df+ 2h)z,-- rg(df--l-2h + 2R) x [ - ~ - ~ ( U r -aft° -~f x )"~+ ( 1 - f l ) z y ] = 0 .

(9)

For Case I of Region B S _ d2Uf f/£f-~-]-+ Itdf'~s ----0

(10)

d2Ur

S~E,---~T-- lt(df + 2h)*,

+

n(df+ 2 h + 2R)Mm

6

(~f~ox \El

-Ur

)

=o.

(ii)

For Case II of Region B

Sf_ d2Uf

.

rcdrMo

/ ~ f . - ~ .t- T

SrErd~--~~ n(df+ 2h)Mc

(U, -- Vf) = 0 Uf)

._.ffM.{. +(1 - fl)Zy} = 0.

(12)

af~ (13)

ZHENHAI XIA: ROLE OF COATINGS IN METAL-MATRIX COMPOSITES

The solutions of equations (14) and (15) for Region C are

For Region C d2Uf Me S f E f - - ~ + x d f - - - ~ - (O r - Uf) = 0

2099

(14)

U c = Cl VI exp(-- ~qx) + C 2 V2 e x p ( - ~ 2 x ) + C 3 V1 exp(al x) + C4 V2 exp(a2x)

d2U~ SrEr -d-~x2- ~r(dr + 2h) ~

(U r -- Ur)

(22)

-{- O'f°° X

+ I r ( 4 + 2h + 2R) (~--~

Ef

) X - - U r M m = 0.

(15)

The solutions of equations (8) and (9) for Region A are A 2z, Ur =d--~rx2 + Al x + A2

U c = Ci exp(-- CtlX) + C2 e x p ( - a 2 x ) + C3 exp(~l x) + C4 exp(a2x) + trr~ x er

(23)

where V1 = 1 + (t 2 -- ot2)/q

(16)

V2 = 1 + (t 2 -- ot~)/q UO = A 3 e x p ( - x / ~ t x )

a, = {p + q + t 2 + [(P + q + t2)2 _ 4pt2]'/2}/2 ~t2 = {p + q + t 2 _ [(p + q + t2)2 _ 4pt2]m}/2.

+ A4 exp(x//-~tx) + ~-~ x

The boundary conditions are ~(df + 2h)x s flMm(df+ 2h + 2R)

(1 -- fl)6 flMm ry

(17)

where

x=0,

UfA = 0 ,

dUe" --=0 dx

(24)

As =V.~Mm(df+ 2k + 2 R ) ] '/2. t L SrE, 6

x --, oo,

The solutions of equations (10) and (1 l) for Case I of Region B are 2zs

2

U~=d~X

+nix +n 2

(18)

+

dU c dx

af~ Ef

(25)

We also require that displacements and forces be continuous at Boundaries A - B and B-C, i.e. For Case I (a > b), at x : a , U B = U c, U~ = UCr, dU~/dx = dUC/dx

U~ = B 3 e x p ( - tx) + B4 exp(tx) 6(dr + 2h)% x -Mm(dr+2h +2R)"

dU c dx

and

(19)

dUBr/dx=dUC/dx,

(26)

and at x = b, U ~ = Uf,~ UrA = UBr, d U k / d x = dU~/dx

The solutions of (12) and (13) for Case II of Region of B are

and

dUg/dx=dU~/dx.

(27)

For Case II (a < b). at x = a ,

U~ = B~ exp(--01x) + B~ e x p ( - 02x) + B~ exp(01 x) + B~ exp(02x)

U A = U~, U A = UBr, dUA/dx = dU~/dx (20) +

f x

and

tiM m

U~ = U c, Ur _ U c, dU~/dx = dU~/dx

+ B~ WI exp(01x) + B~ W2 exp(02x) (1 -

fl)'~y

q=

and

(21)

flM~

where nclfM~ P= S---~'

n(d r + 2h)Mc S,E,h

Ol = {p + q + fit 2 + [(P + q + fit2) 2 - 4flpt2]m}/2

02)/q

W 2 = 1 + (fit 2 -- 02)/q.

dU~/dx=dUC/dx.

(29)

In addition, the shear stresses in the coating at x = a and in the matrix at x = b should be equal to the interfacial failure strength in shear and matrix yielding strength, respectively at

x = a,

h U~ - Ura = - - zi

(30)

6 b vp = - - ~y + -~- af~. Mm ~r

(31)

Mc

02 = {p + q + fit 2 - [(p + q + fit2) 2 - 4flpt2]l/2}/2 W , = 1 + (fit 2 - -

(28)

and at x = b,

U~ = B~ W l exp(--01 x) + B~ W2 e x p ( - 0 2 x )

af~ + --~f x

dUA/dx=dU~/dx,

at x = b,

2100

ZHENHAI XIA: ROLE OF COATINGS IN METAL-MATRIX COMPOSITES

These boundary conditions are used to determine the integration constants in equations (16)-(23). The calculations of stress concentrations and stress distributions were carried out on an IBM AT personal computer using properties of the constituent phases based on SiC-coated C/A1 composites listed in Table 1.

R = 0.5 ktm x i = 300 MPa

7 1.5 P

E 1,0

P

~

3. RESULTS AND DISCUSSION

~

At low stress levels, only Region C where Zm < Zy and z¢ < zi exists. With increasing stress level, Region B arises and grows. Whether Case I or II occurs in the region is dependent of ra and Zy and stresses in the coating and matrix. When stress in the coating at x = 0 is the first to reach z i, Case I arises; otherwise, Case II occurs. With further increasing stress level, Region A arises, where both interracial debonding and matrix yielding takes place. Figure 2 shows the effects of interfacial strength and thickness of the reaction zone on the regions during loading. At the low interracial strength, interfacial debonding occurs before matrix yielding while a large interfacial strength leads to yielding before debonding, Fig. 2(a). With increasing the interfacial strength, the critical stresses resulting in debonding with yielding increase but the critical yielding stress becomes constant when yielding takes place before debonding. (a) A~~____B-1I

_

C 1.2 --

~" ~"

0.4

Debonding Yielding

;/

D e,

/'" "//

// ,///

0

400

2 \.1

3. I. Stress states during loading

2.01.6 ---- R = 1 ~tm

1 of~ = 740 MPa 2 of~ = 2000 MPa

800

1200

0.5

~q

_

N

Xc/'r i

2 -~I~ \

~.

1

I '~X\

j l\,,

---

Xm/~Y

\

z

-i j 0

4

8

?" -".l 12

16

i

i

20

24

x 0tm) Fig. 3. Variations of N, ~¢/~i and Tm/Tyas a function of x. With increasing the thickness R, debonding and yielding occur at lower stress level at any interfacial strength, Fig. 2(b). 3.2. Stress concentrations Figure 3 shows the stress concentration factors for fibre N, coating ~c/Z~ and matrix Zm/"Cyas a function of x at the given stress levels. It can be seen that at low stress level (Region C and Case II of Region B), the factors of N, rc/Ti and 17m/Tyhave the maximum values at x = 0 and decrease with an increase of x. When increasing stress leads to interfacial debonding, with an increase of x, the value of N increases up to a maximum value at a point of x = a, and beyond the point it decreases quickly. The value of z¢/zi is equal to rs/Z~ in the region of debonding and beyond this region it decreases from one to zero while 27rn/'l~y decreases from the maximum value at x = 0 to zero. It is of interest to determine the locations and values of the maximum stress concentrations because they influence the fracture mechanisms and strength of the composites. The maximum stress concentration in fibres is located at x = a. Figure 4 shows

Interfacial strength (MPa) Z

>

(b)

30

2.0 --

"~i = 140 MPa

of~ = 2000 MPa

}20

1.2 0.8

~

_

lo

0.4 -- Region Ct 0

0.5

1.0

R=0.5

1.5

Thickness of reaction zone 0xm) Fig. 2. Stress states of the composites as functions of (a) interfacial bonding strength and (b) thickness of reaction zone.

0

gm

500

1000

Interfacial strength xi (MPa) Fig. 4. Debonding length as a function of interfacial strength.

ZHENHAI XIA: ROLE OF COATINGS IN METAL-MATRIX COMPOSITES

16I

of~

= 2000

/

1.5 1.4 Z

Debonding region

_

1.3 -1.2

MPa

/

_

R = 0 . 2

_

~

R = l~tm // \~_ /e ~ , , / /// / /// 3=0.5

/

Nd/'/,'f""

/

Non-debonding region

"

1.1 1.0 ~ ' 1

400

I

I

I

800

1200

1600

lnterfacial strength x i (MPa) Fig. 5. Maximum stress concentration factor for fibres N=~ as a function of interfacial strength.

2101

can effectively decrease the stress concentration in fibres. However, too low a strength can cause too long debonding length which decreases the efficiency of fibre-reinforcement. Figure 6 shows the effects of the shear modulus and thickness of the coating on Nmax. With an increase of Me, Nma~ decreases for a low interfacial strength, and it increases in the case of strong interfacial bonding. For a middle interfacial bonding, Nma~ increases with increasing of Me up to a maximum value and beyond this point it decreases. Therefore, decreasing the shear modulus of the coating, especially in the range of Me < 70 GPa, is of benefit in relaxing the stress concentration in fibers. 4. VERIFICATION OF THE MODEL

the interfacial debonding length a as a function of 17i. As zi--~ 0, the length becomes infinite and with an increase of r i, it decreases up to zero. This implys that with a strong interfacial bonding, the composites would fail in a brittle manner while a weak interfacial bonding results in debonding and fibre-pullout in the fracture process of the composites. The maximum stress concentration factor for fibres Nm~ as functions of stress level and interfacial bonding strength was calculated and the results show that it remains constant during the initial loading. After the interfacial debonding takes place, Nm~~ decreases with an increase of the stress level. If the matrix yields before debonding, Nmax increases with increasing stress after yielding till the debonding occurs. This indicates that the interfacial debonding can relax the stress concentration in fibres and the matrix yielding increases it. Figure 5 shows the effects of the interfacial bonding strength and thickness of the reaction zone on Nm~. With an increase of interfacial bonding strength, Nm~, increases up to the maximum value at any h, while increasing h leads to an increase of Nm~x at any z~. Therefore, decreasing the interfacial strength

4.1. Comparison with the results from the Griffith relationship In principle, the failure of the fibre coated with the partially consumed coatings can be predicted from an energetic standpoint, as similarly as in the analysis of [1]. The energy required to break the coated fibres at the root of the cracks in the reaction zone would be GfSf+ GcSc. When the coating/fibre interracial bonding is not strong enough to prevent interracial debonding, other energy-absorbing mechanisms such as debonding, pullout etc. take place in the fracture process. Therefore, the total energy absorbed is not necessarily related to the energy of (GfSf+ GcS¢). Following this line of reasoning the critical parameter that defines the onset of the fibre fracture is stress in the fibres. It has been shown that the cracks in the reaction zone result in stress concentration in fibres. This will lead to the premature failure of the fibres during loading, decreasing the composite strength. According to the criterion of the maximum stress, we calculated the fibre failure strength as a function of thickness of

, ~ 1.2 ~1.3

---

m

of® = 2000 MPa R=0.5 p,m 1.2 -

----

From Griffith relationship From present model

h = 2.0 p,m h= 1.21xm

---~-

.....

--

z°

~ 0.8 ".~m c'a~ 0.40'6i~

xi = 100 MPa \"

~

~N°n-deb°nding~

1.1 ,-[~ 0.2 0 z 1.0

I 50

t 100

I 150

Coating modulus M c (GPa) Fig. 6. Maximum stress concentration factor for fibres as a function of coating shear modulus.

0

.......... I

I

I

1

2

3

Thickness of reaction zone R(gm) Fig. 7. Comparison of relations between normalized fibre failure strength O'f/O'~ and thickness of reaction zone predicted by present model and the Griffith relationship.

2102

ZHENHAI XIA: ROLE OF COATINGS IN METAL-MATRIX COMPOSITES

Table 1. Properties of the constituent phases used in calculations Phase

Parameter

Value

Reference

Fibre

Ef Gf df a ~'

390 GPa 3.98 J/rn2 6 ,urn 2200 MPa

IT] [111

Matrix

(SIC) coating

vf

0.4

zy fl Mm

40 MPa 0.1 27 GPa

E~ Me G¢ h

360 GPa 150 GPa 14.5 J/m 2 1.2#m

strength as a function of R is also shown in Fig. 7 and is seen to agree with that from the model under the same condition.

4.2. Comparison with the experimental results for SiC-coated C/AI composites Xia et al. [12] studied the behavior of A356 matrix composites reinforced by PAN-I carbon fibres coated with a duplex-coating of 0.4 # m nickel and 1.2 # m silicon carbide. Figure 8 shows the measured tensile strength of the composites as a function of thickness of the reaction zone. They found that three regions are included: Region I where the composites have high strength with a duplex pullout fracture mode in which fibres are pulled out from the coatings and the coatings are pulled out from the matrix, Region II where the strength decreases with increasing thickness of the reaction zone and only fibre-pullout from the coatings is observed in the fracture surfaces, and Region III where the strength is very low and the fracture is brittle. According to the model, which of fracture mechanisms acts is dependent of the interfacial bonding strength and the strength of the composites is determined by the stress concentration in fibres. With a low zi, interfacial debonding may occur. Because the maximum stress concentration in fibres is located at x = a, the fibres would fail at this point, forming the pullout fracture surfaces in the fracture process of the composites. When the interfacial bonding is strong enough to avoid debonding during loading, the cracks in the reaction zone directly propagate through the fibre/coating interface into the fibres to form the planar fracture surfaces because the maximum stress concentration in fibres is located at the root of the cracks.

[61 [8]

[9]

Reaction layer (AI4Ca)

Er

297.5 GPa

[81

Interface

zs

10 MPa

[10]

the reaction zone, as shown in Fig. 7. The strength decreases with increasing the thickness at any xi. With a low interfacial bonding strength, high fibre failure strength results. When the fibre/ coating interface bonding is strong enough to avoid debonding, the fibre reaches its lowest value in strength. In the case of non-debonding, the fibre strength can be simply predicted from the Grittith relationship af =

(32)

where E = (ErSf + EcSc)/(Sf + Sc)

(33)

G = (GrSf + GcSc)/(Sr+ S¢).

(34)

Numerical constants used in the calculations are shown in Table 1. The normalized fibre failure

"~=

1.2--

Ii \

1.0

I

I

\

Present model

0.8

/.

o

~

0.6

~

0.4

=

0.2 --

"~

0

--

Io

Experimental data [12]

!

~

I

i II

1,7-) I 0.2

I 0.4

t 0.6

I 0.8

I 1.0

R e a c t i o n z o n e t h i c k n e s s to c o a t i n g t h i c k n e s s ( R / h )

Fig. 8. Comparisons between normalized measured composite strength a~/ROM as a function of reaction-zone thickness to coating thickness and that predicted by the present model and the Griflith relationship. I = Region, I, II = Region If, and III = Region III. ROM = tensile strength calculated from equation (35) at crf= o'~'.

ZHENHAI XIA:

ROLE OF COATINGS IN METAL-MATRIX COMPOSITES

T h e s t r e n g t h o f the composites as a f u n c t i o n of the thickness o f the reaction zone has been calculated f r o m the model by applying the rule o f mixtures

O'cu=

O'f Vf-Jt -

¢rm(1

-- Vf).

(35)

In the calculation, the b o n d i n g s t r e n g t h o f the fibre/ coating interface is assumed to be c o n s t a n t a n d equal to 140 M P a [11] in Region I, a n d in Region II, due to diffusion a n d reaction, it increases linearly f r o m 140 M P a to a value at which the interfacial debonding is just avoided. The predicted results show in Fig. 8 indicate a m a x i m u m disagreement o f a b o u t 2 0 % in the range o f c o m p a r i s o n , which is reasonable. Next, the results calculated from e q u a t i o n s (32) a n d (35) were c o m p a r e d with the experimental data. Only in Region III do the calculated results agree with the experimental data. Noticeably, the results bring to light a n i m p o r t a n t fact t h a t high strength o f the composites is maintained by SiC coating even w h e n there is a serious interracial reaction between the m a t r i x a n d the coating. This role o f the coating has been well predicted by the present model. 5. CONCLUSIONS A model has been developed for analysis o f the effects o f coating, plastic d e f o r m a t i o n o f the matrix, interracial b e h a v i o r a n d reaction zone in tensile b e h a v i o r o f fibre-reinforced composites. T h e results o f the present analysis are consistent with those o b t a i n e d f r o m the analysis based o n the Griffith relationship with strong interface b o n d i n g . T h e predictions of the model agree with the experimental d a t a o n SiC-coated C/AI composites. B o t h the theory a n d experiment show t h a t high s t r e n g t h of C/AI composites is m a i n t a i n e d by SiC coating even there is a serious reaction at the c o a t i n g / m a t r i x interface. T h e m a i n results from the model are as follows: (1) T h e fibre/coating interracial d e b o n d i n g relaxes the stress c o n c e n t r a t i o n in fibres while the m a t r i x yielding increases it. (2) T h e lower the coating/fibre interfacial b o n d i n g strength is the lower the stress c o n c e n t r a t i o n in fibres becomes, b u t too low a n interracial s t r e n g t h decreases the efficiency o f fibre-reinforcement. (3) The tensile s t r e n g t h o f the composites c a n be i m p r o v e d by c h o o s i n g the coatings o f low shear m o d u l u s a n d controlling the coating/fibre interracial b o n d i n g s t r e n g t h to a relatively low value. REFERENCES

1. S. Ochiai and Murakami, J. Mater. Sci. 14, 831 (1979). 2. A. G. Metcalfe and M. J. Klein, Composite Materials, Vol. 1 (edited by A. G. Metcalfe). Academic Press, New York (1974). 3. T. Erlurk, V. Gupta, A. S. Argon and J. A. Cornie, ICCM-VI, Vol. 2, pp. 2. 156-2. 160 (1987). 4. R. R. Kiechke and T. W. Clyne, Mater. Sci. Technol. 6, 145 (1990). 5. C. Zweben, Engng Fract. Mech. 6, 1 (1974). AM

41/7~L

2103

6. S. Ochiai and K. Osamura, Metall. Trans. 19A, 1491 (1988). 7. D. D. Hinbeault, R. A. Varin and K. Piekarski, Metall. Trans. 20A, 165 (1989). 8. H. Nayeb-Hashemi and J. Seyyedi, Metall. Trans. 20A, 727 (1989). 9. I. Merkel and U. Messerschmidt, Mater. Sci. Engng 151, 131 (1992). 10. W. H. Hunt Jr, Interfaces in Metal-Matrix Composites (editedby A. K. Dhingra and S. G. Fishman), pp. 3-26. T M S (1986). 11. Zhenhai Xia, Acta Mater. Comp. Sinica 10, No. 1 (1993). 12. Zhenhai Xia, Yaohe Zhou and Zhiying Mao, Mater. Sci. Prog. 5, 448 (1991). APPENDIX Nomenclature a = interracial debonding length A = region of debonding and yielding A t , A 2 , A 3 , A 4 = integration constants b = matrix yielding zone width B = region of debonding or yielding Bl, B2, B3, B4 = integration constants B~, B~, B], B~ = integration constants C = region of neither debonding nor yielding Cj, C 2, C 3, C4 = integration constants df = fibre diameter E c = Young's modulus of coating Ef = Young's modulus of fibre E r = Young's modulus of reaction layer E m = Young's modulus of matrix Gc = critical strain energy release rate for the coating Gf = critical strain energy release rate for the fibre h = thickness of coating M c = shear modulus of coating M m = shear modulus of matrix N = stress concentration factor for fibre N ~ = maximum fibre stress concentration factor R = thickness of reaction layer R O M = composite tensile strength calculated from rule of mixtures as trf = a ? Sc = cross-sectional area of coating Sf = cross-sectional area of fibre Sr = cross-sectional area of reaction layer Uf = displacement of fibre Ur = displacement of reaction layer Vf = fibre volume fraction x = coordinate parallel to fibre /] = slope of matrix shear stress-strain curve after yielding r = shear strain of matrix 6 = thickness of matrix layer in a unity cylinder af~ = stress in fibre at x = oo af = fibre failure strength a~' = fibre strength a m = matrix stress at x = ~ when fibre failure occurs a~u = composite strength Zm= shear stress in matrix % = shear stress in coating • y = yield strength of matrix ~s = frictional shear stress at interface postdebonding zi = interracial bonding shear strength Super scip t : A = Region A B = Region B

C = Region C

2104

ZHENHAI

XIA:

Subscript: c f m r i

= = = = =

coating fibre matrix reaction product interface

ROLE OF COATINGS

IN METAL-MATRIX

COMPOSITES