《复合材料 Composites》课程教学资源（学习资料）第五章 陶瓷基复合材料_fiber18

Availableonlineatwww.sciencedirect.com SCIENCE DIRECT● E噩≈S ELSEVIER Journal of the European Ceramic Society 25(2005)1717-1722 www.elsevier.com/locate/jeurceramsoc Subcritical crack growth processes in SiC/SiC ceramic matrix composites R.H. Jones, C H. Henager Jr Pacific Northwest National Laboratory, MS P8-15, PO. Box 999, Richland, WA 99352, USA Available online 2 February 2005 Abstract Ceramic matrix composites have the potential to operate at high temperatures and are, therefore being considered for a variety of advanced energy technologies such as combustor liners in land-based gas turbo/generators, heat exchangers and advanced fission and fusion reactors Ceramic matrix composites exhibit a range of crack growth mechanisms driven by a range of environmental and nuclear conditions. The crack growth mechanisms include: (1) fiber relaxation by thermal (FR) and irradiation(FIr) processes, (2)fiber stress-rupture(SR),(3)interface removal (Ir)by oxidation, and(4)oxidation embrittlement(OE)resulting from glass formation including effects of glass viscosity. Analysis of these crack growth processes has been accomplished with a combination experimental/modeling effort. Dynamic, high-temperature, in situ crack growth measurements have been made in variable Ar+O2 environments while a Pacific Northwest National Laboratory(Pnnl) developed model has been used to extrapolate this data and to add radiation effects. In addition to the modeling effort, a map showing these mechanisms as a function of environmental parameters was developed. This mechanism map is an effective tool for identifying operating regimes and predicting behavior. The process used to develop the crack growth mechanism map was to: (1) hypothesize and experimentally verify the operative mechanisms, (2)develop an analytical model for each mechanism, and (3)define the operating regime and boundary conditions for each mechanism. A map for SiC/SiC composites has been developed for chemical and nuclear environments as a function of temperature and time o 2004 Elsevier Ltd. All rights reserved. Keyords: Composites; Corrosion; Creep; Fracture; Carbides, Engine applications; Structural applications 1. Introduction peered interfaces between the fiber and matrix, provide ex- cellent fracture properties and fracture toughness values on Silicon carbide is a refractory semiconductor with unique the order of 25 MPam/2. The strength and fracture tough- properties. Because of its thermal, mechanical and chemi- ness are independent of temperature up to the limit of the cal stability, it can be used in extremely harsh environments. fiber stability. Also, these fiber/matrix microstructures im- Pure SiC also provides exceptionally low radioactivity un- part excellent thermal shock and thermal fatigue resistance to der neutron radiation, making it a top candidate for use in these materials so start-up and shut-down cycles and coolant advanced fission and fusion reactors. However, these appli- loss scenarios should not induce significant structural dam cations will require that these composites be optimized for age. For nuclear applications, the radiation resistance of the maximum performance. To accomplish this it will be neces- B phase of Sic imparts excellent radiation resistance. The B sary to understand their high-temperature mechanical, chem- phase of SiC has been shown by numerous studies to have a ical and radiation properties. Ceramic composites made from saturation swelling value of about O 1-0.2%at 800-1000C silicon carbide fibers and silicon carbide matrices(SiCf/Sic) This suggests that composites of Sic/Sic have the poten- are promising because of their excellent high-temperature tial for excellent radiation stability. The purpose of this pa- strength, fracture, creep, corrosion and thermal shock resis- per is to describe the subcritical crack growth behavior of tance. The continuous fiber architecture, coupled with engi- SiCf/SiC composites as this is an element in the creep behav ior of these materials. This analysis is based on the develop- Corresponding author. Tel. +1 509 3764276: fax: +1 509 3760418. ment of crack growth models and the supporting experimental E-mail address: rh. jones @pnl. gov(R H. Jones). 0955-2219/S-see front matter c 2004 Elsevier Ltd. All rights reserved doi: 10.1016/j-jeurceramsoc. 2004.12.015

Journal of the European Ceramic Society 25 (2005) 1717–1722 Subcritical crack growth processes in SiC/SiC ceramic matrix composites R.H. Jones ∗, C.H. Henager Jr. Pacific Northwest National Laboratory, MS P8-15, P.O. Box 999, Richland, WA 99352, USA Available online 2 February 2005 Abstract Ceramic matrix composites have the potential to operate at high temperatures and are, therefore being considered for a variety of advanced energy technologies such as combustor liners in land-based gas turbo/generators, heat exchangers and advanced fission and fusion reactors. Ceramic matrix composites exhibit a range of crack growth mechanisms driven by a range of environmental and nuclear conditions. The crack growth mechanisms include: (1) fiber relaxation by thermal (FR) and irradiation (FIR) processes, (2) fiber stress-rupture (SR), (3) interface removal (IR) by oxidation, and (4) oxidation embrittlement (OE) resulting from glass formation including effects of glass viscosity. Analysis of these crack growth processes has been accomplished with a combination experimental/modeling effort. Dynamic, high-temperature, in situ crack growth measurements have been made in variable Ar + O2 environments while a Pacific Northwest National Laboratory (PNNL) developed model has been used to extrapolate this data and to add radiation effects. In addition to the modeling effort, a map showing these mechanisms as a function of environmental parameters was developed. This mechanism map is an effective tool for identifying operating regimes and predicting behavior. The process used to develop the crack growth mechanism map was to: (1) hypothesize and experimentally verify the operative mechanisms, (2) develop an analytical model for each mechanism, and (3) define the operating regime and boundary conditions for each mechanism. A map for SiC/SiC composites has been developed for chemical and nuclear environments as a function of temperature and time. © 2004 Elsevier Ltd. All rights reserved. Keywords: Composites; Corrosion; Creep; Fracture; Carbides; Engine applications; Structural applications 1. Introduction Silicon carbide is a refractory semiconductor with unique properties. Because of its thermal, mechanical and chemi￾cal stability, it can be used in extremely harsh environments. Pure SiC also provides exceptionally low radioactivity un￾der neutron radiation, making it a top candidate for use in advanced fission and fusion reactors. However, these appli￾cations will require that these composites be optimized for maximum performance. To accomplish this it will be neces￾sary to understand their high-temperature mechanical, chem￾ical and radiation properties. Ceramic composites made from silicon carbide fibers and silicon carbide matrices (SiCf/SiC) are promising because of their excellent high-temperature strength, fracture, creep, corrosion and thermal shock resis￾tance. The continuous fiber architecture, coupled with engi- ∗ Corresponding author. Tel.: +1 509 376 4276; fax: +1 509 376 0418. E-mail address: rh.jones@pnl.gov (R.H. Jones). neered interfaces between the fiber and matrix, provide ex￾cellent fracture properties and fracture toughness values on the order of 25 MPa m1/2. The strength and fracture tough￾ness are independent of temperature up to the limit of the fiber stability. Also, these fiber/matrix microstructures im￾part excellent thermal shock and thermal fatigue resistance to these materials so start-up and shut-down cycles and coolant loss scenarios should not induce significant structural dam￾age. For nuclear applications, the radiation resistance of the
phase of SiC imparts excellent radiation resistance. The
phase of SiC has been shown by numerous studies to have a saturation swelling value of about 0.1–0.2% at 800–1000 ◦C. This suggests that composites of SiC/SiC have the poten￾tial for excellent radiation stability. The purpose of this pa￾per is to describe the subcritical crack growth behavior of SiCf/SiC composites as this is an element in the creep behav￾ior of these materials. This analysis is based on the develop￾ment of crack growth models and the supporting experimental data. 0955-2219/$ – see front matter © 2004 Elsevier Ltd. All rights reserved. doi:10.1016/j.jeurceramsoc.2004.12.015

1718 R H. Jones, C.H. HenagerJr /Journal of the European Ceramic Sociery 25(2005)1717-1722 2. Suberitical crack growth in SiC/Sic Matrix Matrix 2.1. Mechanisms and model development Bonded Pacific Northwest National Laboratory (PNNL) wa mong the first to identify and study time-dependent bridg- ing in ceramic composites-'and we have proposed a crack growth mechanism map based on available experimental data as a function of temperature and oxygen partial pressure for continuous fiber composites with carbon interphases An approach to modeling dynamic time-dependent crack bridging has emerged from the work of Buckner and Rice crack based on the use of weight-functions to calculate crack opening opening displacements. Once a relationship . between V displacement crack-opening displacement and bridging tractions from crack-bridging elements is included, a governing integral Fig. 1. Schematic of frictionally bonded fiber acted upon by force Pr due to equation is obtained that relates the total crack opening, and debonding and sliding across a Mode I crack with opening ut. The lengths the bridging tractions, to the applied load. The solution of deb and l free are shown. this equation gives the force on the crack-bridges and the crack-opening displacement everywhere along the crack CG and Hi-Nicalon fibers as and applied it to a variety of time-dependent bridging cases for linear creep laws 12-14. Recently, a more appropriate Ef=Ao"rPexP(RT bridging relation for creeping fibers has been developed by Cox et al. that provides axial and radial stresses in creeping C(T)otP= Ef=C()o"ptP- fibers with linear and non-linear creep laws where A is a constant, t is time, Q is an activation energy for creeping fibers that also considers the case for interface re- creep, Ris the gas constant and T is temperature, n is the stress moval due to oxidation. We treat discrete fiber bridges as exponent, p is the time-temperature exponent, o is stress, Et opposed to a bridging force distribution because each fiber Is the fiber strain and C(T)is A exp(-POIRT). The unbonded has a different environmental exposure. A non-linear (in time length given by lfree creeps at the bridging stress applied to and stress)creep law is used to compute bridge extensions the fiber. The portion of fiber that is debonded creeps at a stress that varies over the debond length, which is found by 2.2. Enironmental effects: model and mechanism map integration. The creep extension of a bridge becomes 2. 1. Compliance of a frictionally bondedfiber(bridge △lfte=C(T) We introduce an expression for the compliance of a bridg- ing fiber, b, using the assumptions of frictional bonding with a weak, debonding interphase. The frictionally bonded fiber for the free length of fiber and involves an unbonded or free length, Ifree, and a debonded or frictionally bonded and sliding length, deb, for a fiber bridg- Aldeb =C(T)prP-1At0(2)dz=C(T)prP-A ng a crack of opening ur, as shown in Fig. I The free length of fiber, which is not subject to fric- tional forces, is assigned a compliance, pb, and the portion (1+E)(1+n) of the fiber subjected to a frictional sliding resistance along length Deb due to Pf (Fig. I)is assigned a non-linear compli for the debonded length when the axial fiber stress is given ance,b, such that bb=pbPb+Pb[15], where Pb is the by 2D normalized bridge force and 8b, is the bridge displace dependent debonding from fiber contraction due to Poisson o()=A 2rz ment. As suggested by Cox et al. one could include a time- effect and creep deformation, which provides an additional time-dependent fiber compliance term where t is the total creep time, At is the time step, is the axial distance along the fiber measured from the crack face. 2.2.2. Fiber relaxation (FR) due to creep t is the shear stress and 5 is given by Ef/(1-NEm. Time, t, The time-dependent extension of a fiber bridge at elevated is referenced to the inception of each bridge into the bridging temperatures obeys a power-law creep equation for Nicalon- zone and is tracked separately for each bridge

1718 R.H. Jones, C.H. Henager Jr. / Journal of the European Ceramic Society 25 (2005) 1717–1722 2. Subcritical crack growth in SiC/SiC 2.1. Mechanisms and model development Pacific Northwest National Laboratory (PNNL) was among the first to identify and study time-dependent bridg￾ing in ceramic composites1–3 and we have proposed a crack growth mechanism map based on available experimental data as a function of temperature and oxygen partial pressure for continuous fiber composites with carbon interphases4. An approach to modeling dynamic time-dependent crack bridging has emerged from the work of Buckner ¨ 5 and Rice6 based on the use of weight-functions to calculate crack￾opening displacements7. Once a relationship8,9 between crack-opening displacement and bridging tractions from crack-bridging elements is included, a governing integral equation is obtained that relates the total crack opening, and the bridging tractions, to the applied load. The solution of this equation gives the force on the crack-bridges and the crack-opening displacement everywhere along the crack face5–7,10. Begley et al.11 first developed a dynamic model and applied it to a variety of time-dependent bridging cases for linear creep laws12–14. Recently, a more appropriate bridging relation for creeping fibers has been developed by Cox et al.9 that provides axial and radial stresses in creeping fibers with linear and non-linear creep laws. We have developed a similar bridging law for non-linear creeping fibers that also considers the case for interface re￾moval due to oxidation. We treat discrete fiber bridges as opposed to a bridging force distribution because each fiber has a different environmental exposure. A non-linear (in time and stress) creep law is used to compute bridge extensions. 2.2. Environmental effects: model and mechanism map 2.2.1. Compliance of a frictionally bonded fiber (bridge) We introduce an expression for the compliance of a bridg￾ing fiber,Φb, using the assumptions of frictional bonding with a weak, debonding interphase. The frictionally bonded fiber involves an unbonded or free length, lfree, and a debonded or frictionally bonded and sliding length, ldeb, for a fiber bridg￾ing a crack of opening ut, as shown in Fig. 1. The free length of fiber, which is not subject to fric￾tional forces, is assigned a compliance, Φl b, and the portion of the fiber subjected to a frictional sliding resistance along length ldeb due to Pf (Fig. 1) is assigned a non-linear compli￾ance, Φn b, such that δb = Φl bPb + Φn bP2 b [15], where Pb is the 2D normalized bridge force and δb, is the bridge displace￾ment. As suggested by Cox et al.9 one could include a time￾dependent debonding from fiber contraction due to Poisson effect and creep deformation, which provides an additional time-dependent fiber compliance term. 2.2.2. Fiber relaxation (FR) due to creep The time-dependent extension of a fiber bridge at elevated temperatures obeys a power-law creep equation for Nicalon￾Fig. 1. Schematic of frictionally bonded fiber acted upon by force Pf due to debonding and sliding across a Mode I crack with opening ut. The lengths ldeb and lfree are shown. CG and Hi-Nicalon fibers as: εf = Aσnt p exp
−pQ RT = C(T )σnt p ⇒ ε˙f = C(T )σnptp−1 (1) where A is a constant, t is time, Q is an activation energy for creep, R is the gas constant and T is temperature, n is the stress exponent, p is the time–temperature exponent, σ is stress, Ef is the fiber strain and C(T) is A exp(−pQ/RT). The unbonded length given by lfree creeps at the bridging stress applied to the fiber. The portion of fiber that is debonded creeps at a stress that varies over the debond length, which is found by integration. The creep extension of a bridge becomes: lfree = C(T )ptp−1t
Pb 2rf n lfree (2) for the free length of fiber and ldeb = C(T )ptp−1t ldeb 0 σn(z)dz = C(T )ptp−1t ×
Pb 2rf n ldeb
1 − 1 (1 + ξ) n(1 + n) (3) for the debonded length when the axial fiber stress is given by: σ(z) = Pb 2rf − 2τz rf (4) where t is the total creep time, t is the time step, z is the axial distance along the fiber measured from the crack face, τ is the shear stress and ξ is given by fEf/(1 − f)Em. Time, t, is referenced to the inception of each bridge into the bridging zone and is tracked separately for each bridge.

R H. Jones, C.H. Henager: /Journal of the European Ceramic Sociery 25(2005)1717-1722 10 h VS/OE Argon +202 Pa O2 Deflection m Argon Fraction 0.001 Time(s) Domination Fig. 2. Displacement-time curves for single-edge 100011001200130014001500 SiC/SiC Hi-Nicalon composites tested at 1373K in ding for the indicated time In Ar the curve follows the expected p laws while in Ar+ Oz the curve becomes linear in time as given by Eq ( funct Map showing regions of dominant crack growth mechanism of oxygen concentration in the environment and temperature for 2.2.3. Fiber/matrix interphase removal(R) by oxidative SiC/SiC composites When the fiber/matrix interphase is a material that can 2.3. Crack growth mechanism map undergo a gaseous reaction with oxygen then interphase re moval in oxygen-containing environments becomes impor The proposed mechanism map is shown in Fig 3 Fiber tant, as shown by the data in Fig. 2. Previous research has creep relaxation(FR)dominates at high temperatures and the typical 0/90 plain weave CVI-SiC/SiCr materials with a tion energies are high( 600 kJ/mol)and oxidat. p activa- shown that the following interphase recession data applies tion energies are low (50 kJ/mol). Crack extension is dom- lox =3.3 x 10-4e-6014T p08891=R(T. Po,)t thus inated by interface removal (IR) for oxygen concentrations less than -o I when the temperatures are not extreme. We △lox=R(T,Po2)△t (5) observe both kinetic and activation energy changes in ou experimental data consistent with this hypothesis. We define where lox is the recession distance along the fiber/matrix in- the transition from Fr to iR by the locus of points where terphase from the crack face into the composite in m/s, T the crack growth from each mechanism is equal. At higher temperature in K, Po is fractional oxygen concentration, I oxygen concentrations, the fiber/matrix interphase oxidizes is exposure time and Ri is the interface recession rate. We assume that deb is maintained at its value determined by t and is replaced by a glass phase and either oxidation en brittlement(OE)or viscous sliding(VS)mechanisms may and the load on the fiber occur. We propose that interphase glass formation and chan- nel pinch-off (fiber-matrix bonding) at intermediate temper- 2.2. 4. Oxidation of the bridging fiber(OE and sOE) atures where the resultant glass phase is brittle results in O Exposed bridging fibers will undergo oxidation at elevated and the fibers fail since they can no longer slide relative to temperatures according to: 18 the matrix. We define the transition from ir to oe as the fb=1.84×10-7e-4016/Par0.5 (6) locus of points where the fiber/matrix channel pinches-off and oe occurs in a finite crack growth increment(2.5mm where fibox is the oxide thickness grown on the fiber in m, T in this case). At higher temperatures the glass phase is vis- is temperature in K, Po, is fractional oxygen concentration, cous, not brittle and Vs occurs. When the glass phase ha and t is exposure time in s a high viscosity, fibers can fail by rupture since the fiber/matrix bonding leads to stress concentrations- 2.2.5. Fiber stress rupture like replacing an interface with a low frictional sliding stress osed bridging fibe with a higher one. It follows that there will be a temperature rupture relationships obey time-dependent stress above which this stress concentration will not fail the fibers but this will depend on the details of the compositionally de- In(od=23E"R/[RT(n()+C) pendent glass viscosity. The transition from OE to VS/OE is schematic since we do not yet know the glass viscosity nor have we implemented a viscous sliding treatment for the of is fiber strength in MPa, and e, B, and C are fitted model. although such treatments exist. fiber oxidation also ters from single fiber rupture tests in results in loss of strength. which leads to embrittlement via

R.H. Jones, C.H. Henager Jr. / Journal of the European Ceramic Society 25 (2005) 1717–1722 1719 Fig. 2. Displacement-time curves for single-edge notched beam bars of SiC/SiC Hi-Nicalon composites tested at 1373 K in 4-point bending for the indicated time. In Ar the curve follows the expected fiber creep laws while in Ar + O2 the curve becomes linear in time as given by Eq. (5). 2.2.3. Fiber/matrix interphase removal (IR) by oxidative volatilization When the fiber/matrix interphase is a material that can undergo a gaseous reaction with oxygen then interphase re￾moval in oxygen-containing environments becomes impor￾tant, as shown by the data in Fig. 2. Previous research has shown that the following interphase recession data applies to the typical 0/90 plain weave CVI-SiC/SiCf materials with a CVI carbon interphase17. lox = 3.3 × 10−4e−6014/T P0.889 o2 t = Ri(T, Po2 )t thus lox = Ri(T, Po2 )t (5) where lox is the recession distance along the fiber/matrix in￾terphase from the crack face into the composite in m/s, T is temperature in K, Po2 is fractional oxygen concentration, t is exposure time and Ri is the interface recession rate. We assume that ldeb is maintained at its value determined by τ and the load on the fiber. 2.2.4. Oxidation of the bridging fiber (OE and VS/OE) Exposed bridging fibers will undergo oxidation at elevated temperatures according to:18 fibox = 1.84 × 10−7e−4016.8/T Po2 t 0.5 (6) where fibox is the oxide thickness grown on the fiber in m, T is temperature in K, Po2 is fractional oxygen concentration, and t is exposure time in s. 2.2.5. Fiber stress rupture (SR) Exposed bridging fibers will obey time-dependent stress rupture relationships as:19 ln(σf) = 2.3E −
β R [RT (ln(t) + C)] (7) where σf is fiber strength in MPa, and E, β, and C are fitted parameters from single fiber rupture tests in air. Fig. 3. Map showing regions of dominant crack growth mechanism as a function of oxygen concentration in the environment and temperature for SiC/SiC composites. 2.3. Crack growth mechanism map The proposed mechanism map is shown in Fig. 3. Fiber creep relaxation (FR) dominates at high temperatures and low oxygen concentrations, as expected, since creep activa￾tion energies are high (∼600 kJ/mol) and oxidation activa￾tion energies are low (∼50 kJ/mol). Crack extension is dom￾inated by interface removal (IR) for oxygen concentrations less than ∼0.1 when the temperatures are not extreme. We observe both kinetic and activation energy changes in our experimental data consistent with this hypothesis. We define the transition from FR to IR by the locus of points where the crack growth from each mechanism is equal. At higher oxygen concentrations, the fiber/matrix interphase oxidizes and is replaced by a glass phase and either oxidation em￾brittlement (OE) or viscous sliding (VS) mechanisms may occur. We propose that interphase glass formation and chan￾nel pinch-off (fiber–matrix bonding) at intermediate temper￾atures where the resultant glass phase is brittle results in OE and the fibers fail since they can no longer slide relative to the matrix. We define the transition from IR to OE as the locus of points where the fiber/matrix channel pinches-off and OE occurs in a finite crack growth increment (2.5 mm in this case). At higher temperatures the glass phase is vis￾cous, not brittle and VS occurs. When the glass phase has a high viscosity, fibers can fail by rupture since the local fiber/matrix bonding leads to stress concentrations20, rather like replacing an interface with a low frictional sliding stress with a higher one. It follows that there will be a temperature above which this stress concentration will not fail the fibers but this will depend on the details of the compositionally de￾pendent glass viscosity. The transition from OE to VS/OE is schematic since we do not yet know the glass viscosity nor have we implemented a viscous sliding treatment for the model, although such treatments exist21. Fiber oxidation also results in loss of strength, which leads to embrittlement via

1720 R H. Jones, C.H. HenagerJr /Journal of the European Ceramic Sociery 25(2005)1717-1722 fiber stress rupture, 22,23. Fiber stress corrosion should be where K is the irradiation creep compliance for a given mate- accounted for by the SR mechanism since this data was ob- rial,p is the dose rate in dpa s-, and o is the applied stress tained in air. Since predicted fiber stresses in the crack wake For SiC a value of 4. 7 x 10- MPa-dpa"" is used for K. of a dynamic crack are on the order of 800 MPa or smaller, Then, in analogy with the thermal creep analysis but using a SR is difficult to achieve until temperatures above about linear stress relationship gives 1400K △ltee=Kφ△ tlf 2. 4. Irradiation induced creep crack growth(FIR for the free length of fiber and 2.4.1. Irradiation enhanced creep of sic fibers △ldb=Kφ The earliest studies of irradiation-enhanced creep of SiC were reported by Price24 who conducted bend stress relax- for the debonded length of fiber. These terms are then added ation of monolithic B-SiC strips. These strips were held at a using superposition to the thermal creep terms to give the total fixed strain and irradiated at 780, 950 and 1 130C with neu- elongation of the bridging fibers from simultaneous thermal trons in the ebr li fast reactor to a dose of 7.7 x>n/m and irradiation creep. The model can then be run to study the Price reported a substantial enhancement over thermal creep relative rates of each mechanism over this temperature range. More recent studies by Scholz et al. 5 have shown that a similar and even larger creep ef fect was found for p-SiC fibers(SCS-6)irradiated with light 3. Discussion ions. Over the same temperature range as that reported by Price24, the light ion irradiated SiC fibers exhibited a 100x's The materials included in the map(Fig 3)are 2D wo- faster creep rate. Relative to the thermal creep rate at 1000C, en SiC/SiC composites with Nicalon-CG fibers at -40% the irradiation creep rate for the neutron irradiated bulk sic by volume. Lewinsohn et al. 4 discuss the map concept, the ported by Price24 was 100x's faster while the light ion experimental data more fully. Ho owever irradiated fibers was 10.000 times faster The fr domin we have observed that temperature and oxygen concentra- tion regime in Fig. 3 results from thermal creep of the fibers. tion play the most important roles in determining the opera Clearly, the irradiation enhanced creep rate will also cause creep crack growth and must therefore be considered for nu- to include oxidation in the dynamic crack model in addition to the non-linear fiber creep. However, additional modeling remains and more experimentation is planned 2.4.2. Irradiation enhanced creep of siC/Sic composites Crack growth appears to be controlled by FR above the There is no existing irradiation creep data for SiC/Sic composite matrix-cracking threshold at elevated tempera composites as there is for fibers. Therefore, it is necessary to tures in inert environments pnnl and others have deter rely on model predictions of the effects of irradiation on creep mined composite deformation rates2,26-37 and activation crack growth. A dynamic crack growth model developed by Henager and Hoagland, 5 has been used to predict irradiation 0.003 enhanced creep effects on crack growth. We observe that ir- 373K 1373K Thermaic radiation creep of the fibers dominates the fiber deformation process for temperatures below 1273K(1000C)but ther mal creep dominates at higher test temperatures, Fig. 4. This 0.0026 at 800-900C(107.-1173K) at the end implies that we will need to further understand and model bench irradiation creep processes in SiC-based fibers since appar ently that process is important in applications that operate at 1273K or below1000°C 25. Fiber relaxation due to thermal and irradiation 0.002 0.0018051011031.1021032510331073.51074107 The time-dependent extension of a fiber bridge at elevated Time(s) mperatures still obeys the power-law creep as given by Eq (I)but now also has a portion that is proportional to the irra- Fig. 4. Irradiation creep as a function of temperature of SiC/SiC composi diation dose rate and stress Scholz showed that irradiation with Hi-Nicalon fibers using a fission damage spectrum and damage rate creep could be given as f 0.44 dpa/year. The curves shown include thermal and irradiation creep f the bridging fibers. At 1273 K the thermal crack velocity is equal to the E= Koo steady state velocities but continue to decrease with increasing time 3 irradiation-induced crack velocity. Note that the crack velocities are not

1720 R.H. Jones, C.H. Henager Jr. / Journal of the European Ceramic Society 25 (2005) 1717–1722 fiber stress rupture16,22,23. Fiber stress corrosion should be accounted for by the SR mechanism since this data was ob￾tained in air. Since predicted fiber stresses in the crack wake of a dynamic crack are on the order of 800 MPa or smaller, SR is difficult to achieve until temperatures above about 1400 K. 2.4. Irradiation induced creep crack growth (FIR) 2.4.1. Irradiation enhanced creep of SiC fibers The earliest studies of irradiation-enhanced creep of SiC were reported by Price24 who conducted bend stress relax￾ation of monolithic
-SiC strips. These strips were held at a fixed strain and irradiated at 780, 950 and 1130 ◦C with neu￾trons in the EBR II fast reactor to a dose of 7.7 × 1025 n/m2. Price reported a substantial enhancement over thermal creep over this temperature range. More recent studies by Scholz et al.25 have shown that a similar and even larger creep ef￾fect was found for
-SiC fibers (SCS-6) irradiated with light ions. Over the same temperature range as that reported by Price24, the light ion irradiated SiC fibers exhibited a 100×’s faster creep rate. Relative to the thermal creep rate at 1000 ◦C, the irradiation creep rate for the neutron irradiated bulk SiC reported by Price24 was 100×’s faster while the light ion irradiated fibers was 10,000 times faster. The FR domina￾tion regime in Fig. 3 results from thermal creep of the fibers. Clearly, the irradiation enhanced creep rate will also cause creep crack growth and must therefore be considered for nu￾clear applications. 2.4.2. Irradiation enhanced creep of SiC/SiC composites There is no existing irradiation creep data for SiC/SiC composites as there is for fibers. Therefore, it is necessary to rely on model predictions of the effects of irradiation on creep crack growth. A dynamic crack growth model developed by Henager and Hoagland,15 has been used to predict irradiation enhanced creep effects on crack growth. We observe that ir￾radiation creep of the fibers dominates the fiber deformation process for temperatures below 1273 K (1000 ◦C) but ther￾mal creep dominates at higher test temperatures, Fig. 4. This implies that we will need to further understand and model irradiation creep processes in SiC-based fibers since appar￾ently that process is important in applications that operate at or below 1000 ◦C. 2.5. Fiber relaxation due to thermal and irradiation creep The time-dependent extension of a fiber bridge at elevated temperatures still obeys the power-law creep as given by Eq. (1) but now also has a portion that is proportional to the irra￾diation dose rate and stress. Scholz25 showed that irradiation creep could be given as: ε˙ = Kφσ˙ (8) where K is the irradiation creep compliance for a given mate￾rial, φ˙ is the dose rate in dpa s−1, and σ is the applied stress. For SiC a value of 4.7 × 10−6 MPa−1 dpa−1 is used for K. Then, in analogy with the thermal creep analysis but using a linear stress relationship gives: lfree = Kφ˙ Pb 2rf tlfree (9) for the free length of fiber and ∆ldeb = Kφ˙ Pb 4rf ∆tldeb (10) for the debonded length of fiber. These terms are then added using superposition to the thermal creep terms to give the total elongation of the bridging fibers from simultaneous thermal and irradiation creep. The model can then be run to study the relative rates of each mechanism. 3. Discussion The materials included in the map (Fig. 3) are 2D wo￾ven SiC/SiC composites with Nicalon-CG fibers at ∼40% by volume. Lewinsohn et al.4 discuss the map concept, the materials, and the experimental data more fully. However, we have observed that temperature and oxygen concentra￾tion play the most important roles in determining the opera￾ble crack growth mechanisms. Therefore, it was imperative to include oxidation in the dynamic crack model in addition to the non-linear fiber creep. However, additional modeling remains and more experimentation is planned. Crack growth appears to be controlled by FR above the composite matrix-cracking threshold at elevated tempera￾tures in inert environments. PNNL and others have deter￾mined composite deformation rates1,2,26–37 and activation Fig. 4. Irradiation creep as a function of temperature of SiC/SiC composite with Hi-Nicalon fibers using a fission damage spectrum and damage rate of 0.44 dpa/year. The curves shown include thermal and irradiation creep of the bridging fibers. At 1273 K the thermal crack velocity is equal to the irradiation-induced crack velocity. Note that the crack velocities are not steady state velocities but continue to decrease with increasing time

R H. Jones, C.H. Henager: /Journal of the European Ceramic Sociery 25(2005)1717-1722 energies under these conditions and they match quite well the fiber thermal limits. There is a need for additional stress with activation energies for fiber about 500-600 rupture data as a function of oxygen concentration. kJ/mol. Our dynamic crack growth model agrees reasonably While thermal creep of polymer derived ceramic fibers is well with measured crack growth rates and these activation often non-linear, or viscous-like, in time and stress, irradia- tion creep of these same fibers appears to be linear in both When oxygen is introduced during the crack growth test- time(dose)and applied stress. The fiber thermal creep has an ing the deformation rates increase and the activation energy activation energy of about 600 kJ/mol. The irradiation creep decreases to about 50 kJ/mol, in agreement with carbon ox- equation assumes a temperature independent regime below idation processes. Significantly, the crack growth kinetics 1173K(900C)and an activation energy of 50 kJ/mol for change from non-linear to linear since now the bridge compli- temperatures greater than 1173 K. The creep rate is linear in ance is dominated by the linear portion as lfree lox approach dose rate and stress. We observe that irradiation creep of the and exceed deb, Fig. 2. Again, our model agrees well with fibers dominates the fiber deformation process for tempera- these changes in both kinetics and activation energies. The tures below 1273 K(1000C)but thermal creep dominates at transition between the FR and Ir mechanisms is defined as higher test temperatures, Fig 4. This implies that we will need the locus of points where the crack growth rates of each mech- to further understand and model irradiation creep processes anism are roughly equal. This was determined by choosing an in SiC-based fibers since apparently that process is important oxygen concentration where the crack velocity doubled com- in applications that operate at or below 1000C. There is little pared to the velocity without any oxygen. This curve is steep understanding of the mechanisms of irradiation creep in these as shown in Fig. 2 due in part to the high activation energy fibers, whereas the thermal creep data can be understood by of the fiber creep process. It is bounded at high temperatures analogy to creep in viscous solids. The creep mechanisms in by fiber stress rupture mechanisms the fibers may be distinct from those that operate in the crys- Transitions from IR to either OE or VS/OE mechanisms talline SiC-matrix just by virtue of the nanocrystalline nature are shown. We find that there is a competition between of the fibers, even the stoichiometric fibers. The linear creep specimen failure due to Ir relative to the time for pinch-off response suggests that a Nabarro-Herring creep mechanism and oe to occur. The dynamics are handled by removing may be operating but this remains to be shown conclusively those fibers from the bridging zone that have an oxide thick ness greater than some critical value, such as the interphase thickness. However, this transition is crack length(specimen 4. Conclusion size) and interphase thickness dependent. The size effect occurs since Oe depends on total fiber exposure time, which a dynamic crack growth model with the following fea- is dependent on crack length. Interphase thickness effects tures has been developed: (1) it is based on the weight arise due to our criterion that pinch-off occurs prior to the function method using discrete fiber bridges, (2)it contains onset of oE. The computations shown here are for an inter- non-linear bridge extension laws based on fiber-creep kinet- phase thickness of 150 nm. Other plausible OE mechanisms ics for Nicalon-CG and Hi-Nicalon fibers, (3)it contains only require a critical oxide thickness that is not interphase bridge extension laws for the case of interphase removal, thickness dependent, 39. However, such mechanisms will and(4)it provides fully dynamic crack tracking using a still exhibit a specimen size effect or history effect. Transi- critical-stress-intensity propagation criterion. The model re- tions from OE (pinch-off with brittle glass phase)to VS/oE produces the time-dependent crack growth kinetics observed (non-brittle, viscous glass phase) depend on the viscosity of experimentally in specimens of Nicalon-CG and Hi-Nicalon the glass which is strongly dependent on glass composition. 0/90 woven composites. The transition from non-linear crack Thus, these transitions are not rigorously defined here growth kinetics to linear growth kinetics is also reproduced and will have to wait for future work. By incorporating by the model by comparing crack growth rates under FR or existing models of viscous interphase mechanics, we will IR domination. Using the activation energy for the oxidation be able to understand the effects of viscosity on fiber stress of carbon in the model it correctly predicted this change from concentrations non-linear to linear crack growth kinetics By implementing The database for fiber stress rupture is mainly limited to a simple"fiber removal"algorithm, where the criterion for tests in air so dependence on oxygen concentration is lack- removal is based either on a critical oxide thickness or stress ing. SR competes with OE and IR at temperatures higher rupture threshold, we can also map out transitions between than about 1373 K for oxygen concentrations near 0. 2%. The crack growth due to OE and Sr. This model is being used to onset of Sr occurs at 1373 K in air during dynamic crack predict the effects of fiber stress rupture and neutron irradia- growth according to our model and this onset is predict tion, where there is no data on composite material. A map of to shift to 1423 K for lower oxygen concentrations. Without the crack growth mechanism as a function of environmental detailed data as a function of oxygen concentration, we can oxygen concentration and temperature was developed with not be more quantitative. The map suggests that SR shifts to assumption about the transition between mechanisms and this higher temperatures as the oxygen concentration decreases. has been very effective in identifying optimum environmen- The boundary between FR and Sr is suggested to occur at tal regimes for using these materials. The model and resulting

R.H. Jones, C.H. Henager Jr. / Journal of the European Ceramic Society 25 (2005) 1717–1722 1721 energies under these conditions and they match quite well with activation energies for fiber creep, about 500–600 kJ/mol. Our dynamic crack growth model agrees reasonably well with measured crack growth rates and these activation energies. When oxygen is introduced during the crack growth test￾ing the deformation rates increase and the activation energy decreases to about 50 kJ/mol, in agreement with carbon ox￾idation processes. Significantly, the crack growth kinetics change from non-linear to linear since now the bridge compli￾ance is dominated by the linear portion as lfree + lox approach and exceed ldeb, Fig. 2. Again, our model agrees well with these changes in both kinetics and activation energies. The transition between the FR and IR mechanisms is defined as the locus of points where the crack growth rates of each mech￾anism are roughly equal. This was determined by choosing an oxygen concentration where the crack velocity doubled com￾pared to the velocity without any oxygen. This curve is steep as shown in Fig. 2 due in part to the high activation energy of the fiber creep process. It is bounded at high temperatures by fiber stress rupture mechanisms. Transitions from IR to either OE or VS/OE mechanisms are shown. We find that there is a competition between specimen failure due to IR relative to the time for pinch-off and OE to occur. The dynamics are handled by removing those fibers from the bridging zone that have an oxide thick￾ness greater than some critical value, such as the interphase thickness. However, this transition is crack length (specimen size) and interphase thickness dependent. The size effect occurs since OE depends on total fiber exposure time, which is dependent on crack length. Interphase thickness effects arise due to our criterion that pinch-off occurs prior to the onset of OE. The computations shown here are for an inter￾phase thickness of 150 nm. Other plausible OE mechanisms only require a critical oxide thickness that is not interphase thickness dependent38,39. However, such mechanisms will still exhibit a specimen size effect or history effect. Transi￾tions from OE (pinch-off with brittle glass phase) to VS/OE (non-brittle, viscous glass phase) depend on the viscosity of the glass which is strongly dependent on glass composition. Thus, these transitions are not rigorously defined here and will have to wait for future work. By incorporating existing models of viscous interphase mechanics, we will be able to understand the effects of viscosity on fiber stress concentrations. The database for fiber stress rupture is mainly limited to tests in air so dependence on oxygen concentration is lack￾ing. SR competes with OE and IR at temperatures higher than about 1373 K for oxygen concentrations near 0.2%. The onset of SR occurs at 1373 K in air during dynamic crack growth according to our model and this onset is predicted to shift to 1423 K for lower oxygen concentrations. Without detailed data as a function of oxygen concentration, we can￾not be more quantitative. The map suggests that SR shifts to higher temperatures as the oxygen concentration decreases. The boundary between FR and SR is suggested to occur at the fiber thermal limits. There is a need for additional stress rupture data as a function of oxygen concentration. While thermal creep of polymer derived ceramic fibers is often non-linear, or viscous-like, in time and stress, irradia￾tion creep of these same fibers appears to be linear in both time (dose) and applied stress. The fiber thermal creep has an activation energy of about 600 kJ/mol. The irradiation creep equation assumes a temperature independent regime below 1173 K (900 ◦C) and an activation energy of 50 kJ/mol for temperatures greater than 1173 K. The creep rate is linear in dose rate and stress. We observe that irradiation creep of the fibers dominates the fiber deformation process for tempera￾tures below 1273 K (1000 ◦C) but thermal creep dominates at higher test temperatures, Fig. 4. This implies that we will need to further understand and model irradiation creep processes in SiC-based fibers since apparently that process is important in applications that operate at or below 1000 ◦C. There is little understanding of the mechanisms of irradiation creep in these fibers, whereas the thermal creep data can be understood by analogy to creep in viscous solids. The creep mechanisms in the fibers may be distinct from those that operate in the crys￾talline SiC-matrix just by virtue of the nanocrystalline nature of the fibers, even the stoichiometric fibers. The linear creep response suggests that a Nabarro-Herring creep mechanism may be operating but this remains to be shown conclusively. 4. Conclusion A dynamic crack growth model with the following fea￾tures has been developed: (1) it is based on the weight￾function method using discrete fiber bridges, (2) it contains non-linear bridge extension laws based on fiber-creep kinet￾ics for Nicalon-CG and Hi-Nicalon fibers, (3) it contains bridge extension laws for the case of interphase removal, and (4) it provides fully dynamic crack tracking using a critical-stress-intensity propagation criterion. The model re￾produces the time-dependent crack growth kinetics observed experimentally in specimens of Nicalon-CG and Hi-Nicalon 0/90 woven composites. The transition from non-linear crack growth kinetics to linear growth kinetics is also reproduced by the model by comparing crack growth rates under FR or IR domination. Using the activation energy for the oxidation of carbon in the model it correctly predicted this change from non-linear to linear crack growth kinetics. By implementing a simple “fiber removal” algorithm, where the criterion for removal is based either on a critical oxide thickness or stress rupture threshold, we can also map out transitions between crack growth due to OE and SR. This model is being used to predict the effects of fiber stress rupture and neutron irradia￾tion, where there is no data on composite material. A map of the crack growth mechanism as a function of environmental oxygen concentration and temperature was developed with assumption about the transition between mechanisms and this has been very effective in identifying optimum environmen￾tal regimes for using these materials. The model and resulting

1722 R H. Jones, C.H. Henager J: /Journal of the European Ceramic Sociery 25(2005)1717-1722 mechanism map is helping us develop and understand crack 18. Zhu, Y. T, Taylor, S. T, Stout, M.G., Butt, D. P and Lowe, T growth mechanisms and to design improved composite ma C, Kinetics of thermal, passive oxidation of Nicalon fibers.J.4m. Ceram soc.,1998,81,655 19. DiCarlo, J. A, Yun, H. M, Morscher, G. N. and Goldsby, J. C. perature ceramic-matrix composites ll. Cera. Trans., 1995, 58 20. Glime, w. H. and Cawley, J. D, Stress concentration due to This research was supported by Basic Energy Sciences fiber-matrix fusion in ceramic.ms mposites. Am Ceram Soc. United States Department of Energy, under Contract no DE 998,81,2597 ACo6-76RLO 1830 with Pacific Northwest National Labo- 21. Nair, SV, Jakus, K and Lardner, T J, Mechanics of matrix cracking in fiber reinforced ceramic composites containing a viscous interface. ratory, which is operated for the U.S. Department of Energy Mech. mater 199112 229 by Battelle Memorial Institute 22. Yun, H. M. and DiCarlo, J. A, Time/temperature trength of Sic and Al203-based fibers. Ceram. References 23. Tressler, R. E and DiCarlo, J. A, Creep and rupture of advanced ce- amic fiber reinforcements, in h mperature ceramIc-matrix com 1. Henager Jr, C. H. and Jones, R, H, High-temperature plasticity ef- 24. Price, R. J, Properties of silicon carbide for nuclear fuel particle fects in bridged cracks and subcritical crack growth in ceramic com- oatings. Nucl. Technol. 1977. 35. 320 posites. Mater: Sci. Eng, 4, 1993, A166, 211 25. Scholz, R, Mueller, R. and Lesueur, D, Light ion irradiation creep of 2. Henager Jr, C. H and Jones, R. H, Subcritical crack growth in CVI Textron SCS-6 silicon carbide fibers. J. Nuc. Mater. 2002. 307-311 silicon carbide reinforced with Nicalon fibers; experiment and model. J. Am. Ceram Soc. 1994.77. 2381 26. Abbe, F, Vicens, J. and Chermant, J. L, Creep behavior and mi 3. Henager Jr, C. H, Jones, R. H, Windisch Jr, C. F, Stackpoole, M rostructural characterization of a ceramic matrix composite.J.Mater M. and Bordia, R, Time dependent, environmentally assisted crack 1989,8,1026 owth in Nicalon-fiber-reinforced SiC composites at elevated tem- 27. Chermant, J. L, Abbe, F. and Kervadec, D, On the creep of long y perature. Metall. Mater: Trans. A, 1996, 27A, 839 ceramic fibers reinforced ceramic matrix. In Creep Fract. Eng. Mater. Struc., Proc. Int. Conf. 5th, 1993, p. 371 Environmentally-induced failure mechanism mapping for conti 28. Wu, X and Holmes, J. W, Tensile creep and creep-strain recovery be- fiber, ceramic composites Ceram. Trans., 1999, 96, 351 havior of silicon carbide fiber/calcium aluminosilicate matrix ceral 5. Buckner. H. Z Angew Math. Mech. 1970. 46. 529 6. Rice, J. R, Some remarks on elastic crack-tip stress fields 29. Grathwohl, G, Meier, B and Wang, P, Creep of fiber and whisker re- Solids Struct. 1972.8. 751 inforced ceramics, glass-ceramics and glasses. Key Eng. Mater, 1995. 7. Fett, T, Mattheck, C. and Munz, D, On the calculation of 108-110,243 pening displacement from the stress intensity factor. Eng 30. Evans, A. G. and Weber, C, Creep damage in SiC/SiC composites later. Sci. Eng, A, 1996 8. Marshall, D. B, Cox, B. N. and Evans, A. G, Mechanics of matrix 31. Mumm, D. R, Morris, W, Dadkhah, M. S and Cox, B. N, Subcriti- cracking in brittle-matrix fiber composites. Acta Metall, 1985, 33 cal crack growth in ceramic composites at high temperature measured sing digital image correlation, in thermal and mechanical test meth- 9. Cox, B. N, Sridhar, N.an ods and behavior of continuousfi ber composites. ASTM Spec eeping fibers. Acta Mater, 2000, 48, 4137. ech.Pub.1997.sTP1309.102 10. Cox, B. N. and Marshall, D. B, Stable and unstable solutions for 32. Mizuno, M., Zhu, S, Kagawa, Y. and Kaya, H, Stress, strain, and bridged cracks in various specimens. Acta Metall. Mater, 1991, 39, elastic modulus behavior of Sic-fiber/SiC composites during creep and cyclic fatigue tests. Key Eng. Mater, 1997, 132-136, 1942 M.R., Cox, B N. and McMeeking, R M, Time dependent 33. Cox, B and Zok, F, Recent advances in fibrous ceramic composites growth in ceramic matrix composites with creeping fibers. Acta In Brittle Matrix Compos. 5. Proc. Int. Symp., 5th, 1997, p. 497 Mate:,1995.43.3927 34. wilshire, B, Carreno, F. and Percival, M. J. L, Tensile creep and 12. Begley, M.R., Evans, A G. and McMeeking, R. M, Creep rupture p fracture of a fiber-reinforced SiC/SiC composite. Scr. Mate in ceramic matrix composites with creeping fibers. J. Mech. Phys. 998.39.729 Sol,1995,43,72 35. Chermant, J.-L. and Boitier, G, The importance of damage and slow 13. Begley, M.R., Cox, B. N. and McMeeking, R. M, Creep crack crack growth in the creep behavior of growth with small scale bridging in ceramic matrix composites. Acta Idv Compos. Mater, 1999, 8, 77 Metall. Mater:. 1997. 45. 2897 36. Zhu, S, Mizuno, M, Kagawa, Y 14. Cox, B N, Marshall, D. B, McMeeking, R. M. and Begley, M.R., H, Creep and fatigue behavior in Hi-Nicalon-fiber-reinforced silicon Matrix cracking in ceramic matrix composites with fiber creep. Solid arbide composites at high temperatures. J. m. Ceram. Soc., 1999. Mech.4ppl.4ppl.,1997,49,353 15. Henager Jr, C. H. and Hoagland, R. G, Subcritical crack growth in 37. Tressler, R. E, Rugg, K. L, Bakis, C. E. and Lamon, J, Effects of CVI SiCf/SIC composites at elevated temperatures: Dynamic crack matrix cracking on the creep of Sic-SiC microcomposites. Key Eng wth model. Acta Materialia. 2001 Mater,1999,164/165,297 16. DiCarlo. J. A or high- 38. Evans, A G, Zok, F W, McMeeking, R. M. and Du, Z. Z, Models of mperature fiber reinforcements. Ceramurgia, 1998, 28 high-temperature, environmentally assisted embrittlement in rinO dat ion of the agron nte face ip ngea on- be aei fones 3. Hnmberitlem et mro e to r era mic a r and basis aa ceron. silicon carbide composite. J.Am. Ceram. Soc., 1997, 80, 569 Soc.,1995,78,2097

1722 R.H. Jones, C.H. Henager Jr. / Journal of the European Ceramic Society 25 (2005) 1717–1722 mechanism map is helping us develop and understand crack growth mechanisms and to design improved composite ma￾terials. Acknowledgements This research was supported by Basic Energy Sciences, United States Department of Energy, under Contract no. DE￾AC06-76RLO 1830 with Pacific Northwest National Labo￾ratory, which is operated for the U.S. Department of Energy by Battelle Memorial Institute. References 1. Henager Jr., C. H. and Jones, R. H., High-temperature plasticity ef￾fects in bridged cracks and subcritical crack growth in ceramic com￾posites. Mater. Sci. Eng., A, 1993, A166, 211. 2. Henager Jr., C. H. and Jones, R. H., Subcritical crack growth in CVI silicon carbide reinforced with Nicalon fibers; experiment and model. J. Am. Ceram. Soc., 1994, 77, 2381. 3. Henager Jr., C. H., Jones, R. H., Windisch Jr., C. F., Stackpoole, M. M. and Bordia, R., Time dependent, environmentally assisted crack growth in Nicalon-fiber-reinforced SiC composites at elevated tem￾perature. Metall. Mater. Trans. A, 1996, 27A, 839. 4. Lewinsohn, C. A., Henager Jr., C. H. and Jones, R. H., Environmentally-induced failure mechanism mapping for continuous- fiber, ceramic composites. Ceram. Trans., 1999, 96, 351. 5. Buckner, H., ¨ Z. Angew Math. Mech., 1970, 46, 529. 6. Rice, J. R., Some remarks on elastic crack-tip stress fields. Int. J. Solids Struct., 1972, 8, 751. 7. Fett, T., Mattheck, C. and Munz, D., On the calculation of crack opening displacement from the stress intensity factor. Eng. Fract. Mech., 1987, 27, 697. 8. Marshall, D. B., Cox, B. N. and Evans, A. G., Mechanics of matrix cracking in brittle-matrix fiber composites. Acta Metall., 1985, 33, 2013. 9. Cox, B. N., Sridhar, N. and Argento, C. R., A bridging law for creeping fibers. Acta Mater., 2000, 48, 4137. 10. Cox, B. N. and Marshall, D. 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