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Availableonlineatwww.sciencedirect.com SCIENCE E噩≈S Journal of the European Ceramic Society 24(2004)2339-234 www.elsevier.com/locate/jeurceramsoc Thermal shock resistance of fibrous monolithic Si3 N4/bn ceramics Young-Hag Koha, b,s*, Hae-Won Kima, Hyoun-Ee Kima, John W.Halloran a School of Materials Science and Engineering, Seoul National University, Seoul, 151-742, South Korea b Materials Science and Engineering Department, University of Michigan, Ann Arbor, MI48109-2136, USA Received 15 January 2003: received in revised form 25 June 2003: accepted 6 July 2003 Abstract Thermal shock resistance of fibrous monolithic Si3 N4/BN ceramic was investigated by measuring the strength retention after varying the temperature difference(AT)up to 1400C and was compared with that of monolithic Si3N4 Monolithic Si3 N4 showed catastrophic drop in flexural strength above AT of 1000C, while FM showed negligible reduction in flexural strength without critical temperature difference(AT). Two parameters, such as the resistance to crack initiation(R) and crack propagation(r). were used in order to explain the thermal shock behaviors of fibrous monolith and monolithic Si3N4. Furthermore crack interac- tions during flexural testing, such as delamination cracks and crack deflection, were characterized and were related to the work-of- racture (WoF) C) 2003 Elsevier Ltd. All rights reserved. Keywords: BN; Composites; Fibrous monoliths: Si3N4; Thermal shock 1. Introduction there are some possible methods to increase the thermal shock resistance of materials. For example, the addition Fibrous monoliths have been regarded as promising of ductile secondary phase into Al2O3 matrix increases materials for structural applications because of the the thermal shock resistance due to both reduced elastic noncatastrophic failure due to its unique modulus and increased fracture toughness. Also, flaw- architecture. 1-7 Fibrous monoliths are sintered or hot- tolerant material, such as fiber(or whisker)-reinforced pressed monolithic ceramics with a distinct fibrous tex- ceramics and laminated ceramics shows excellent ther ture consisting of strong cell and weak cell boundary mal shock resistance due to the increased resistance to that act as a easy crack path. One of the most promis- crack propagation through crack interactions with ing fibrous monoliths for high temperature applications toughening agents (fiber, whisker and weak inter is Si3N4/BN system because of its high strength and face) 6- However, so far, in spite of its importance for oxidation resistance at elevated temperature. -7 high temperature applications, no research has beer Since these composite materials are candidates as the done on thermal shock resistance of fibrous monolith high-temperature applications (e.g. in gas turbine In this paper, we have investigated thermal shock engines), it is inevitable to involve some kind of thermal resistance of fibrous monolithic Si3 N,/BN ceramics with shock loading. Most ceramics showed catastrophe temperature difference ranging from 800 to 1400C, by drops in mechanical properties, such as flexural measuring the retention of mechanical properties, such strength, elastic modulus, after thermal shock above the as flexural strength and work-of-fracture (WOF). For critical temperature(AT). -l5 This catastrophic drop the purpose of comparison, monolithic Si3 N4 was also in mechanical properties after thermal shock have lim- tested under the same conditions. ited the wide applications at high-temperatures Thermal shock resistance is dependent on several pri mary mechanical properties, such as fracture toughness, 2. Experimental fracture behavior, fracture strength, elastic modulus and coefficient of thermal expansion of material. 11, 2 Hence, 2. 1. Billet fabrication Fibrous monolithic Si3N4/BN ceramic was fabricated E-mail address: younghag(@engin. umich.edu (Y -H. Koh) using coextrusion process to produce a structure with 0955-2219S. see front matter C 2003 Elsevier Ltd. All rights reserved. doi:10.1016/S0955-2219(03)00644-7
Thermal shock resistance of fibrous monolithic Si3N4/BN ceramics Young-Hag Koha,b,*, Hae-Won Kima , Hyoun-Ee Kima , John W. Halloranb a School of Materials Science and Engineering, Seoul National University, Seoul, 151-742, South Korea bMaterials Science and Engineering Department, University of Michigan, Ann Arbor, MI 48109-2136, USA Received 15 January 2003; received in revised form 25 June 2003; accepted 6 July 2003 Abstract Thermal shock resistance of fibrous monolithic Si3N4/BN ceramic was investigated by measuring the strength retention after varying the temperature difference (�T) up to 1400 �C and was compared with that of monolithic Si3N4. Monolithic Si3N4 showed catastrophic drop in flexural strength above �T of 1000 �C, while FM showed negligible reduction in flexural strength without critical temperature difference (�Tc). Two parameters, such as the resistance to crack initiation (R0 ) and crack propagation (R0000), were used in order to explain the thermal shock behaviors of fibrous monolith and monolithic Si3N4. Furthermore, crack interactions during flexural testing, such as delamination cracks and crack deflection, were characterized and were related to the work-offracture (WOF). # 2003 Elsevier Ltd. All rights reserved. Keywords: BN; Composites; Fibrous monoliths; Si3N4; Thermal shock 1. Introduction Fibrous monoliths have been regarded as promising materials for structural applications because of the noncatastrophic failure due to its unique architecture.17 Fibrous monoliths are sintered or hotpressed monolithic ceramics with a distinct fibrous texture consisting of strong cell and weak cell boundary that act as a easy crack path.1 One of the most promising fibrous monoliths for high temperature applications is Si3N4/BN system because of its high strength and oxidation resistance at elevated temperature.47 Since these composite materials are candidates as the high-temperature applications (e.g. in gas turbine engines), it is inevitable to involve some kind of thermal shock loading. Most ceramics showed catastrophic drops in mechanical properties, such as flexural strength, elastic modulus, after thermal shock above the critical temperature (�Tc).1115 This catastrophic drop in mechanical properties after thermal shock have limited the wide applications at high-temperatures. Thermal shock resistance is dependent on several primary mechanical properties, such as fracture toughness, fracture behavior, fracture strength, elastic modulus and coefficient of thermal expansion of material.11,12 Hence, there are some possible methods to increase the thermal shock resistance of materials. For example, the addition of ductile secondary phase into Al2O3 matrix increases the thermal shock resistance due to both reduced elastic modulus and increased fracture toughness.14 Also, flawtolerant material, such as fiber (or whisker)-reinforced ceramics and laminated ceramics shows excellent thermal shock resistance due to the increased resistance to crack propagation through crack interactions with toughening agents (fiber, whisker and weak interface).1618 However, so far, in spite of its importance for high temperature applications, no research has been done on thermal shock resistance of fibrous monolith. In this paper, we have investigated thermal shock resistance of fibrous monolithic Si3N4/BN ceramics with temperature difference ranging from 800 to 1400 �C, by measuring the retention of mechanical properties, such as flexural strength and work-of-fracture (WOF). For the purpose of comparison, monolithic Si3N4 was also tested under the same conditions. 2. Experimental 2.1. Billet fabrication Fibrous monolithic Si3N4/BN ceramic was fabricated using coextrusion process to produce a structure with 0955-2219/$ - see front matter # 2003 Elsevier Ltd. All rights reserved. doi:10.1016/S0955-2219(03)00644-7 Journal of the European Ceramic Society 24 (2004) 2339–2347 www.elsevier.com/locate/jeurceramsoc * Corresponding author. E-mail address: younghag@engin.umich.edu (Y.-H. Koh).����
Y.H. Koh et al. Journal of the European Ceramic Society 24(2004)2339-2347 uniaxially aligned 250 micron cells of composition commercially available tester Grindo-sonic model Si3 N4(E-10, Ube Industries, Tokyo, Japan) with 6 MK4x, J W. Lemmon, St, Louis, MO, USA). 20 wt%Y2O3(99.9%, Johnson Matthey Electronics, MA USA)and 2 wt. Al,O3(HP-DBM, Reynolds, Bauxite, AK, USA), separated by 15-25 micron boron nitride 3. Results (HCP, Advanced Ceramics Corp Cleveland, OH, USA cell boundaries. Further details on the fabrication of 3. 1. Microstructure and mechanical properties before fibrous monoliths are described elsewhere. 4 For com thermal shock parison, monolithic Si3 N4 with 6 wt %Y2O3 and 2 wt% Al2O3 as sintering aids was also fabricated. The The typical microstructure of fibrous monolithic green billets were hot-pressed at 1740C under an Si3 N4/BN ceramic(FM)is shown in Fig. 1. Low mag applied pressure of 25 MPa for 2 h in a flowing N2 nification SEM micrographs of polished sections, shows atmosphere. The density of the specimens was measured three-dimensional representations of the sub-millimeter using the Archimedes method and the theoretical density structure of fibrous monoliths. The polycrystalline sili- of the specimens was estimated by the rule of mixture con nitride cells appear in dark contrast, while the con- tinuous boron nitride cell boundaries appear in bright 2.2. Specimen preparation contrast. The Si3 N4 cells are surrounded by the cell boundaries consisting of bn particles bonded with The thermal shock resistance was determined by yttriumaluminosilicate. measuring the retention of the flexural strength of The mechanical properties of monolithic Si3 N4 and water-quenched specimen. Specimens were machined FM samples are summarized in Table l. For FM, the nto a bar shape with dimensions of 3x4x45 mm and measured density (p) was slightly higher than theoretical ground with a 600-grit diamond wheel. The tensile side value(based on 82.5 vol. Si3 N4 cells and 17.5 vol% of the specimens was polished using diamond paste BN cell boundaries for fibrous monoliths), implying full down to 3 um, and subsequently chamfered to minimize densification of both Si3 N4 cell and BN cell boundary machining flaws. Also, the side surfaces of each speci- materials occurred. Elastic modulus (E)and flexural men were polished down to 30 um strength(MOR) of FM were slightly lower than those of monolithic Si3 N4, while apparent WoF increased 23. Thermal shock test remarkably due to the noncatastrophic failure through extensive crack interactions along the weak Bn cell Thermal shock test was carried out in a vertical tube boundaries furnace at temperatures between 800C and 1400C in The typical flexural responses of monolithic Si3 N4 and laboratory air. The furnace was heated at a heating rate FM are shown in Fig. 2. As expected, monolithic Sign of 10 C/min and maintained at exposure temperatures. showed higher strength but negligible apparent wo Polished specimens, suspended at the end of a platinum wire, were inserted into the hot-zone from the top and were soaked for 30 min to induce the homogeneous temperature distribution. After exposure, the specimens were quickly dropped into the water bath with a capa city of 5000 cc. The temperature of water bath did not increase notably after dropping the specimen 2.4. Mechanical test and characterization The flexural strength after thermal shock test was measured at room temperature by a four-point flexural configuration at a cross-head speed of 0.5 mm/min, and inner- and outer-spans of 20 and 40 mm, respectively The load versus crosshead deflection response and the work of fracture, calculated by determining the area under the load-crosshead deflection curve and dividing 250μm it by twice the cross-sectional area of the sample, are reported. Also, crack propagation during flexural Fig. I. Low magnification SEM micrographs of polished strength test after thermal shock was observed by an shows three-dimensional representations of the submillimeter of fibrous monoliths. The polycrystalline silicon nitride cells optical microscope and an SEM microscope. Elastic dark contrast and the continuous boron nitride cell boundaries are in moduli were measured by the impulse technique using a bright contrast. Courtesy of Bruce King)
uniaxially aligned �250 micron cells of composition Si3N4 (E-10, Ube Industries, Tokyo, Japan) with 6 wt.% Y2O3 (99.9%, Johnson Matthey Electronics, MA, USA) and 2 wt.% Al2O3 (HP-DBM, Reynolds, Bauxite, AK, USA), separated by 15�25 micron boron nitride (HCP, Advanced Ceramics Corp., Cleveland, OH, USA) cell boundaries. Further details on the fabrication of fibrous monoliths are described elsewhere.1,4 For comparison, monolithic Si3N4 with 6 wt.% Y2O3 and 2 wt.% Al2O3 as sintering aids was also fabricated. The green billets were hot-pressed at 1740 �C under an applied pressure of 25 MPa for 2 h in a flowing N2 atmosphere. The density of the specimens was measured using the Archimedes method and the theoretical density of the specimens was estimated by the rule of mixture. 2.2. Specimen preparation The thermal shock resistance was determined by measuring the retention of the flexural strength of water-quenched specimen. Specimens were machined into a bar shape with dimensions of 3�4�45 mm and ground with a 600-grit diamond wheel. The tensile side of the specimens was polished using diamond paste down to 3 mm, and subsequently chamfered to minimize machining flaws. Also, the side surfaces of each specimen were polished down to 30 mm. 2.3. Thermal shock test Thermal shock test was carried out in a vertical tube furnace at temperatures between 800 �C and 1400 �C in laboratory air. The furnace was heated at a heating rate of 10 �C/min and maintained at exposure temperatures. Polished specimens, suspended at the end of a platinum wire, were inserted into the hot-zone from the top and were soaked for 30 min to induce the homogeneous temperature distribution. After exposure, the specimens were quickly dropped into the water bath with a capacity of 5000 cc. The temperature of water bath did not increase notably after dropping the specimen. 2.4. Mechanical test and characterization The flexural strength after thermal shock test was measured at room temperature by a four-point flexural configuration at a cross-head speed of 0.5 mm/min, and inner- and outer-spans of 20 and 40 mm, respectively. The load versus crosshead deflection response and the work of fracture, calculated by determining the area under the load–crosshead deflection curve and dividing it by twice the cross-sectional area of the sample, are reported. Also, crack propagation during flexural strength test after thermal shock was observed by an optical microscope and an SEM microscope. Elastic moduli were measured by the impulse technique using a commercially available tester (Grindo-sonic model MK4x, J. W. Lemmon, St, Louis, MO, USA).20 3. Results 3.1. Microstructure and mechanical properties before thermal shock The typical microstructure of fibrous monolithic Si3N4/BN ceramic (FM) is shown in Fig. 1. Low magnification SEM micrographs of polished sections, shows three-dimensional representations of the sub-millimeter structure of fibrous monoliths. The polycrystalline silicon nitride cells appear in dark contrast, while the continuous boron nitride cell boundaries appear in bright contrast. The Si3N4 cells are surrounded by the cell boundaries consisting of BN particles bonded with yttriumaluminosilicate. The mechanical properties of monolithic Si3N4 and FM samples are summarized in Table 1. For FM, the measured density (�) was slightly higher than theoretical value (based on 82.5 vol.% Si3N4 cells and 17.5 vol.% BN cell boundaries for fibrous monoliths), implying full densification of both Si3N4 cell and BN cell boundary materials occurred. Elastic modulus (E) and flexural strength (MOR) of FM were slightly lower than those of monolithic Si3N4, while apparent WOF increased remarkably due to the noncatastrophic failure through extensive crack interactions along the weak BN cell boundaries. The typical flexural responses of monolithic Si3N4 and FM are shown in Fig. 2. As expected, monolithic Si3N4 showed higher strength but negligible apparent WOF Fig. 1. Low magnification SEM micrographs of polished sections, shows three-dimensional representations of the submillimeter structure of fibrous monoliths. The polycrystalline silicon nitride cells appear in dark contrast and the continuous boron nitride cell boundaries are in bright contrast. (Courtesy of Bruce King). 2340 Y.-H. Koh et al. / Journal of the European Ceramic Society 24 (2004) 2339–2347
Y.H. Koh et al. Journal of the European Ceramic Society 24(2004)2339-2347 2341 because of catastrophic failure [Fig. 2(A)]. On the other 3. 2. Strength retention hand, FM exhibited noncatastrophic failure due to its The thermal shock resistance was observed by mea- unique architecture, comprised of strong Si3 N4 cell and suring the retention of the flexural strength after ther weak BN cell boundary, resulting in high apparent mal shock test, as shown in Fig. 4. For monolithic WOF [Fig. 2(B). Moreover, the apparent strength Si3 N4, the traditional thermal shock behavior of brittle retention after the first failure was above 50% of origi material was observed, that is, the flexural strength nal strength, showing the noncatastrophic. This non- decreased rapidly after thermal shock with temperature catastrophic nature was attributed to the extensive difference of 1000C [Fig. 4(A)]. However, the flexural crack interactions, such as crack delaminations and strength of fM after thermal shock test was not chan crack deflections, as shown in Fig. 3. For fibrous ged much [Fig. 4(B)l, showing the excellent thermal monoliths, the crack propagates through the weak cell shock resistance. Moreover, there was no critical tem- boundaries to reduce the applied stress. Similar crack perature (AT), at which the strength decreases propagations have been observed in many different catastrophically, up to 1400C. kinds of fibrous monoliths 1-5 3. 22. fracture behavior 3.2. Mechanical properties after thermal shock lithic Si N4 and FM were not basically changed. After thermal shock. the fracture behaviors of mor When a material(monolithic Si3 N4 or FM)is sub jected to a rapid decrease in temperature(AT), the sur- face of the component is placed under tension and the interior under compression. If the tensile stress devel oped on the surface exceeds the strength of the material the cracks are generated, leading to a rapid drop in flexural strength 11-15 Fig. 3. Optical photograph of crack propagation of the fibrous monolithic Si]N4/ BN ceramic after flexural testing. Extensive crack (B)Fibrous Monolith interactions. such as crack delamination and crack deflection. were Crosshead Displacement I mm I ≈600. Fig. 2. Flexural response of (A) monolithic Si3 N4 and (B)fibrous (B)Fibrous Monolith monolithic Si3N4/BN ceramic before thermal shock test. Monolithic Si3N4 showed brittle fracture, while fibrous monolith showed graceful racture due to unique architecture. Note, retained apparent stress after first drop is above 50%(B) Table 0600800100012001400 Summarized mechanical properties of monolithic Si3N4 and fibrous monolithic Si3N4/BN ceramic Temperature Difference[C I p(g/cc) E(GPa) MOR (MPa) WoF (kJ/m) Fig. 4. Flexural strength of (A)monolithic Si3 N4 and (B)fibrous 3N4/bn ceramic after thermal shock with Monolithic si3N43.27±0.1318±4832±4 differene Flexural strength of monolithic Si3N Fibrous monolith3.09±0.1276±3416±34 5.94±1.34 strophically after thermal shock with AT=1000C; howe monolith showed negligible decrease in flexural strength
because of catastrophic failure [Fig. 2(A)]. On the other hand, FM exhibited noncatastrophic failure due to its unique architecture, comprised of strong Si3N4 cell and weak BN cell boundary, resulting in high apparent WOF [Fig. 2(B)]. Moreover, the apparent strength retention after the first failure was above 50% of original strength, showing the noncatastrophic. This noncatastrophic nature was attributed to the extensive crack interactions, such as crack delaminations and crack deflections, as shown in Fig. 3. For fibrous monoliths, the crack propagates through the weak cell boundaries to reduce the applied stress. Similar crack propagations have been observed in many different kinds of fibrous monoliths.15 3.2. Mechanical properties after thermal shock When a material (monolithic Si3N4 or FM) is subjected to a rapid decrease in temperature (�T), the surface of the component is placed under tension and the interior under compression. If the tensile stress developed on the surface exceeds the strength of the material, the cracks are generated, leading to a rapid drop in flexural strength.1115 3.2.1. Strength retention The thermal shock resistance was observed by measuring the retention of the flexural strength after thermal shock test, as shown in Fig. 4. For monolithic Si3N4, the traditional thermal shock behavior of brittle material was observed, that is, the flexural strength decreased rapidly after thermal shock with temperature difference of 1000 �C [Fig. 4(A)]. However, the flexural strength of FM after thermal shock test was not changed much [Fig. 4(B)], showing the excellent thermal shock resistance. Moreover, there was no critical temperature (�Tc), at which the strength decreases catastrophically, up to 1400 �C. 3.2.2. Fracture behavior After thermal shock, the fracture behaviors of monolithic Si3N4 and FM were not basically changed, as Table 1 Summarized mechanical properties of monolithic Si3N4 and fibrous monolithic Si3N4/BN ceramic Samples � (g/cc) E (GPa) MOR (MPa) WOF (kJ/m2 ) Monolithic Si3N4 3.27�0.1 318�4 832�46 Negligible Fibrous monolith 3.09�0.1 276�3 416�34 5.94�1.34 Fig. 2. Flexural response of (A) monolithic Si3N4 and (B) fibrous monolithic Si3N4/BN ceramic before thermal shock test. Monolithic Si3N4 showed brittle fracture, while fibrous monolith showed graceful fracture due to unique architecture. Note, retained apparent stress after first drop is above 50% (B). Fig. 3. Optical photograph of crack propagation of the fibrous monolithic Si3N4/BN ceramic after flexural testing. Extensive crack interactions, such as crack delamination and crack deflection, were observed. Fig. 4. Flexural strength of (A) monolithic Si3N4 and (B) fibrous monolithic Si3N4/BN ceramic after thermal shock with temperature difference (�T). Flexural strength of monolithic Si3N4 reduced catastrophically after thermal shock with �T=1000 �C; however, fibrous monolith showed negligible decrease in flexural strength. Y.-H. Koh et al. / Journal of the European Ceramic Society 24 (2004) 2339–2347 2341��
Y.H. Koh et al. Journal of the European Ceramic Society 24(2004)2339-2347 shown in Fig. 5, that is, monolithic Si3N4 showed cata- ticles in the as-hot pressed material are already micro- strophic failure (not shown), while FM showed cracked. Hence, thermal shock damage seems to be noncatastrophic failure regardless of temperature d absorbed within the bn cell boundaries which would ference. Furthermore, with the increase in temperature decrease the cell boundary fracture resistance, enabling difference, more extensive crack interactions were easier crack deflection and higher WOF. The specimens observed. The increase in apparent stress after fist drop shocked with the highest temperature difference implies the midplane shear stress after thermal shock (AT=1400C)had the most extensive crack delamina- The apparent WOF of the FM specimens increased tions, as shown in Fig. 7(D). This remarkable increase remarkably after thermal shock test, as shown in Fig. 6. in crack delamination is attributed to not only pre- The WOF is higher if there is a large retained load once ferential crack propagation caused by thermal stress but fracture begins, and strongly depends upon the extent of also oxidized damage layer during exposure to air crack interactions and delamination. The thermally The change of surface morphology after thermal shocked specimens exhibited higher retained strength shock test is shown in Fig. 8. Up to the temperature and extensive crack delamination. Thermal shock difference of 1200oC, the surface was not damaged damage seems to be absorbed within the bn cell (not shown). However, with temperature difference of boundaries, which would decrease the cell boundary 1400C, the surface(both BN cell boundary and fracture resistance, enabling easier crack deflection and Si3N4 cell) was damaged to some extent due to the higher WOF oxidation 3.2.3. Crack propagation 3.2.4. Load-bearing capacit The increased crack interactions in the thermally The thermal stress developed on surface and interface shocked sample, manifested by crack path, are clearly of Si3 N4 and bn after the thermal shock affected the shown in Fig. 7A-D. After thermal shock, crack inter- flexural response of FM upon subsequent room tem- actions (crack delamination and crack deflection) perature testing, as shown in Fig. 9. The retained occurred more extensively compared to the specimen strength after the fist drop(Ist drop/lst peak) was not before the thermal shock(Fig. 3). Pronounced crack basically changed within the range between 40% and delamination occurred by the thermal shock of 800C 55%, meaning the excellent load-bearing capacity for [Fig. 7(A)], and further long crack delamination was actual applications. However, the normalized maximum observed after the thermal shock of 1200C [Fig. 7(C). strength (2nd peak/lst peak) increased after thermal The tendency for crack delamination in FM ceramics is shock test. This result means that the first peak was influenced by the interfacial crack resistance of the BN- caused by the crack initiation on the surface; thus, the ontaining cell boundary. 7. The increase in WOF after surface was slightly weakened due to the thermal stress thermal shock suggests that thermal shock reduces the Furthermore, the thermal stress developed in interface interfacial crack resistance of the cell boundary, which of Si, N4 and bn promoted extensive crack interactions is a composite of boron nitride and glass. The Bn par resulting in increased woF. A△T=800c (B)△T=1000c 0号 (c)△T=1200c D)△T=1400c 200400600800100012001400 Crosshead Displacement I mm] Temperature Difference[Cl lexural responses of fibrous monolithic Si3N4/BN Fig. 6. Work-of-fracture (woF) of fibrous monolithic Si3 N4/BN ermal shock with temperature difference(AT) of(A)80 800oC ceramic thermal shock with temperature difference (AT) oC,(C)1200C, and(D)1400C. All samples exhibited Fibrous monolith exhibited significant woF due to extensive crack
shown in Fig. 5, that is, monolithic Si3N4 showed catastrophic failure (not shown), while FM showed noncatastrophic failure regardless of temperature difference. Furthermore, with the increase in temperature difference, more extensive crack interactions were observed. The increase in apparent stress after fist drop implies the midplane shear stress after thermal shock. The apparent WOF of the FM specimens increased remarkably after thermal shock test, as shown in Fig. 6. The WOF is higher if there is a large retained load once fracture begins, and strongly depends upon the extent of crack interactions and delamination. The thermally shocked specimens exhibited higher retained strength and extensive crack delamination. Thermal shock damage seems to be absorbed within the BN cell boundaries, which would decrease the cell boundary fracture resistance, enabling easier crack deflection and higher WOF. 3.2.3. Crack propagation The increased crack interactions in the thermally shocked sample, manifested by crack path, are clearly shown in Fig. 7A–D. After thermal shock, crack interactions (crack delamination and crack deflection) occurred more extensively compared to the specimen before the thermal shock (Fig. 3). Pronounced crack delamination occurred by the thermal shock of 800 �C [Fig. 7(A)], and further long crack delamination was observed after the thermal shock of 1200 �C [Fig. 7 (C)]. The tendency for crack delamination in FM ceramics is influenced by the interfacial crack resistance of the BNcontaining cell boundary.7,8 The increase in WOF after thermal shock suggests that thermal shock reduces the interfacial crack resistance of the cell boundary, which is a composite of boron nitride and glass. The BN particles in the as-hot pressed material are already microcracked.1 Hence, thermal shock damage seems to be absorbed within the BN cell boundaries, which would decrease the cell boundary fracture resistance, enabling easier crack deflection and higher WOF. The specimens shocked with the highest temperature difference (�T=1400 �C) had the most extensive crack delaminations, as shown in Fig. 7(D). This remarkable increase in crack delamination is attributed to not only preferential crack propagation caused by thermal stress but also oxidized damage layer during exposure to air. The change of surface morphology after thermal shock test is shown in Fig. 8. Up to the temperature difference of 1200 �C, the surface was not damaged (not shown). However, with temperature difference of 1400 �C, the surface (both BN cell boundary and Si3N4 cell) was damaged to some extent due to the oxidation. 3.2.4. Load-bearing capacity The thermal stress developed on surface and interface of Si3N4 and BN after the thermal shock affected the flexural response of FM upon subsequent room temperature testing, as shown in Fig. 9. The retained strength after the fist drop (1st drop/1st peak) was not basically changed within the range between 40% and 55%, meaning the excellent load-bearing capacity for actual applications. However, the normalized maximum strength (2nd peak/1st peak) increased after thermal shock test. This result means that the first peak was caused by the crack initiation on the surface; thus, the surface was slightly weakened due to the thermal stress. Furthermore, the thermal stress developed in interface of Si3N4 and BN promoted extensive crack interactions, resulting in increased WOF. Fig. 5. Flexural responses of fibrous monolithic Si3N4/BN ceramic after thermal shock with temperature difference (�T) of (A) 800 �C, (B) 1000 �C, (C) 1200 �C, and (D) 1400 �C. All samples exhibited graceful fractures. Fig. 6. Work-of-fracture (WOF) of fibrous monolithic Si3N4/BN ceramic after thermal shock with temperature difference (�T). Fibrous monolith exhibited significant WOF due to extensive crack interactions. 2342 Y.-H. Koh et al. / Journal of the European Ceramic Society 24 (2004) 2339–2347
Y.H. Koh et al. Journal of the European Ceramic Society 24(2004)2339-2347 2343 3 mm 3 mm (c) (D) mm 3 mm Fig. 7. Optical photographs of crack propagation of fibrous monolithic Si3 N4/BN ceramic after thermal shock with temperature difference(An)of (A)800C,(B)1000C,(C)1200C, and (D)1400C during flexural testing. All samples showed extensive crack interactions, such delaminations and crack deflections 4. Discussion aligned in the transverse direction. Therefore mechan- ical properties, such as elastic modulus, coefficient of The fracture strength of thermally shocked monolithic thermal expansion(CTE) and Poissons ratio, of FM Si3N4 is strongly dependent on the magnitude of tensile sample show anisotropy, as described in Table 2 stress developed on the surface, that is, if the tensile The elastic modulus of monolithic silicon nitride was stress exceeds its strength, the cracks are generated on sig d the transverse modulus of the the surface, resulting in catastrophic drop in flexural FM was less than half the longitudinal modulus, due to trength. However, for FM sample, the fracture the Bn, which has a small c-axis modulus. The long- strength of FM sample is less sensitive to surface flaws: itudinal thermal expansion of the Fm was slightly less therefore, the resistance to crack propagation is a more than monolithic silicon nitride, decreased by the a-axis critical factor than the resistance to crack initiation, BN, while the transverse thermal expansion of the FM which is critical for brittle monolithic Si3 N4. However, was much larger, increased by the c-axis BN. Poisson's pre-existing cracks on BN cell boundaries after hot- ratios were estimated from rule-of-mixture by taking pressing(T=1740oC)also affects the flexural response, 0.27 and 0.2 for Si3N4 and BN, respectively resulting in crack interactions. Therefore, some factors, The magnitude of thermal stress induced by the same such as the magnitude of thermal stress on surface, exposure will be different, depending on the cell align thermal shock resistance parameter and pre-existing ment (longitudinal and transverse direction). The tradi cracks tional approach to evaluate the thermal shock resistance is based on quenching the specimen from an elevated 4.1. Magnitude of thermal stress on the surface(ors) temperature into a quenching media and measuring the fracture strength of the material. Neglecting the heat Considering the structure of this uniaxial FM (Fig. 1), transfer and size effects, the maximum tensile stress it is noted that the elastic modulus and thermal expan- (ors) generated on the surface of the specimen can be sion coeficient is different in the transverse and long according itudinal directions. In addition, the hexagonal BN is ors =(Ea/(1-v).AT strongly textured, with the high stiffness/low expan sion a-axis aligned preferentially in the longitudinal where E, a and v represent the elastic modulus, the direction and the lower stiffness/higher expansion c-axis coefficient of thermal expansion(CTE)and Poissons
4. Discussion The fracture strength of thermally shocked monolithic Si3N4 is strongly dependent on the magnitude of tensile stress developed on the surface, that is, if the tensile stress exceeds its strength, the cracks are generated on the surface, resulting in catastrophic drop in flexural strength. However, for FM sample, the fracture strength of FM sample is less sensitive to surface flaws; therefore, the resistance to crack propagation is a more critical factor than the resistance to crack initiation, which is critical for brittle monolithic Si3N4. However, pre-existing cracks on BN cell boundaries after hotpressing (T=1740 �C) also affects the flexural response, resulting in crack interactions. Therefore, some factors, such as the magnitude of thermal stress on surface, thermal shock resistance parameter and pre-existing cracks, are discussed. 4.1. Magnitude of thermal stress on the surface (sTS) Considering the structure of this uniaxial FM (Fig. 1), it is noted that the elastic modulus and thermal expansion coefficient is different in the transverse and longitudinal directions. In addition, the hexagonal BN is strongly textured,19 with the high stiffness/low expansion a-axis aligned preferentially in the longitudinal direction and the lower stiffness/higher expansion c-axis aligned in the transverse direction. Therefore mechanical properties, such as elastic modulus, coefficient of thermal expansion (CTE) and Poisson’s ratio, of FM sample show anisotropy, as described in Table 2. The elastic modulus of monolithic silicon nitride was significantly higher, and the transverse modulus of the FM was less than half the longitudinal modulus, due to the BN, which has a small c-axis modulus. The longitudinal thermal expansion of the FM was slightly less than monolithic silicon nitride, decreased by the a-axis BN, while the transverse thermal expansion of the FM was much larger, increased by the c-axis BN. Poisson’s ratios were estimated from rule-of-mixture by taking 0.27 and 0.2 for Si3N4 21 and BN,22 respectively. The magnitude of thermal stress induced by the same exposure will be different, depending on the cell alignment (longitudinal and transverse direction). The traditional approach to evaluate the thermal shock resistance is based on quenching the specimen from an elevated temperature into a quenching media and measuring the fracture strength of the material. Neglecting the heat transfer and size effects, the maximum tensile stress (TS) generated on the surface of the specimen can be calculated according to:11 TS ¼ ð Þ E=ð Þ 1 � DT ð1Þ where E, and � represent the elastic modulus, the coefficient of thermal expansion (CTE) and Poisson’s Fig. 7. Optical photographs of crack propagation of fibrous monolithic Si3N4/BN ceramic after thermal shock with temperature difference (�T) of (A) 800 �C, (B) 1000 �C, (C) 1200 �C, and (D) 1400 �C during flexural testing. All samples showed extensive crack interactions, such as crack delaminations and crack deflections. Y.-H. Koh et al. / Journal of the European Ceramic Society 24 (2004) 2339–2347 2343�����
