Effects of interfacial residual stress on mechanical behavior of SiCf/SiC composites

Abstract: Layer-structured interphase, existing between reinforcing fiber and ceramics matrix, is an indispensable constituent for fiber-reinforced ceramic composites due to its determinant role in the mechanical behavior of the composites. However, the interphase may suffer high residual stress because of the mismatch of thermal expansion coefficients in the constituents, and this can exert significant influence on the mechanical behavior of the composites. Here, the residual stress in the boron nitride (BN) interphase of continuous SiC fiber-reinforced SiC composites was measured using a micro-Raman spectrometer. The effects of the residual stress on the mechanical behavior of the composites were investigated by correlating the residual stress with the mechanical properties of the composites. The results indicate that the residual stress increases from 26.5 to 82.6 MPa in tension as the fabrication temperature of the composites rises from 1500 to 1650 °C. Moreover, the increasing tensile residual stress leads to significant variation of tensile strain, tensile strength, and fiber/matrix debonding mode of the composites. The sublayer slipping of the interphase caused by the residual stress should be responsible for the transformation of the mechanical behavior. This work can offer important guidance for residual stress adjustment in fiber-reinforced ceramic composites.

Keywords: ceramic matrix composites; Raman spectroscopy; mechanical properties; residual stress 

1 Introduction

Continuous fiber-reinforced ceramic matrix composites (CFCMCs) are promising materials for replacing some nickel-base super-alloys in hot section components of advanced aero-engines [1,2]. CFCMCs are mainly composed of reinforcing fiber, ceramic matrix, and layer-structured interphase between them. The multiple constituents endow CFCMCs with much more favorable mechanical characteristics over conventional ceramics, such as high damage tolerance to cracks and non-brittle fracture [3,4]. These favorable mechanical characteristics combined with other advantages, such as low density and high temperature corrosion/oxidation stability, enable aero-engines to operate with increasing efficiency and reducing emissions [5]

Among the multiple constituents, an elaborately tailored interphase is a prerequisite to obtain CFCMCs with optimized mechanical properties [6,7]. So far, layer-structured pyrolytic carbon (PyC) and boron nitride (BN) are the most commonly used interphase for CFCMCs [8], as their moderate shear strength can activate various toughening mechanisms, including crack arrest/deflection/branching, fiber/matrix debonding, and fiber pull-out. Various research has shown that an elaborated interphase is quite necessary to obtain CFCMCs with both high strength and high toughness, as it can induce crack deflection along the fiber surface without degrading the stress-bearing capability of the fiber [9,10]. The mechanical role of the interphase in the mechanical behavior of the composites is demonstrated to be closely related with its thickness [11–13], crystallinity [14,15], and sublayer sequence [16–18]. In terms of mechanics, the residual stress in the interphase may also play an important role as it can redistribute the stress within the composites and thus regulate the overall mechanical behavior. However, the relationship between the residual stress and the mechanical behavior is still not well understood. 

For fiber-reinforced composites, residual stress almost inevitably exists in the interphase, considering the discontinuity of chemical composition and the mismatch of thermal expansion existing between the interphase with other adjacent constituents. Research has shown that interfacial residual stress in SiC fiber-reinforced Ni–Cr–Al composites can be as high as ~1.9 GPa and found that vacuum heat treatment can reduce the residual stress [19]. Moreover, the interfacial residual stress is demonstrated to be responsible for the premature formation of cracks in the composites [20–22]. SiCf/SiC (continuous SiC fiber-reinforced SiC matrix composites) is one of the most widely studied CFCMCs and residual stress in the composites has also received increasing attention recently. Research has shown that SiCf/SiC prepared by silicon melt infiltration exhibits residual tensile stress as high as ~1.45 and 0.5–0.7 GPa in the matrix and the fiber, respectively [23]. Moreover, the silicon phase of the composites shows heterogeneous residual stress, with compressive stress of ~180 MPa in the intra-tow silicon while ~300 MPa in the matrix silicon [24]. Although recently there is growing 
research investigating the residual stress in SiCf/SiC, to the best knowledge of the authors, the interfacial residual stress of the composites and its effects on the mechanical behavior have not been studied. 

In this study, the interfacial residual stress of SiCf/SiC composites prepared by nano-infiltration and transient eutectic-phase (NITE) method was investigated using a micro-Raman spectrometer. The effects of the residual stress on the mechanical properties and the fracture morphologies of the composites were revealed. Besides, the mechanisms of the mechanical and microstructural evolution under the residual stress were also proposed. This study can offer new insight for the relationship between the interfacial residual stress and the mechanical behavior of CFCMCs. 

2 Experimental 

2. 1 Material preparation 

The SiCf/SiC composites were prepared by an NITE process. Firstly, continuous SiC fiber cloths (Cansas 3303, Fujian Leaoasia New Material Ltd., Quanzhou, China) were coated with BN interphase (~600 nm in thickness) via chemical vapor deposition (CVD) method using BCl3–NH3–H2–N2 as the source gases. Subsequently, the fiber cloths were impregnated with a SiC slurry, which mainly consisted of SiC powder (~0.7 μm; Weifang Kaihua Silicon Carbide Micropowder Ltd., Weifang, China), 5 wt% binder (polyvinyl butyral, PVB), and 10 wt% sintering additives (SiO2–Al2O3–Y2O3). The impregnated fiber cloths were then cut and stacked to form 70 mm × 70 mm × 5 mm preforms. The preforms were solidified at 120 ℃ and then pyrolyzed at 900 ℃ in flowing Ar atmosphere. Finally, the pyrolyzed preforms were densified at 1500–1650 ℃ for 2 h under pressure of 20 MPa to obtain SiCf/SiC composites. 

2. 2 Residual stress determination 

The principle for residual stress determination using Raman spectroscopy is that residual stress is linearly related to Raman shift [25,26]. The Raman spectrum of the interphase was characterized by a combined equipment of micro-Raman spectrometer (Renishaw InVia, 532 nm laser, 10 mW, Blue Scientific Limited, Cambridge, UK) and atomic force microscope (AFM; SPA400/SPI3800N, Seiko Inc., Japan). Using a focused laser as the excitation source, the resolution of the micro-Raman spectrometer almost reaches ~0.5 μm. This makes it feasible to selectively probe the interphase. As both chemical and mechanical factors can lead to Raman shift, extracting the Raman shift caused by mechanical factors is critical to measure the residual stress. To simplify the measurement, it is assumed that the interphase residual stress is totally originated from the matrix formation of the composites. Therefore, the effective Raman shift can be obtained as follows: (1) The Raman spectra of the as-coated interphase on the fiber are collected and the Raman shift Δλ1 is measured; (2) the Raman spectra of the interphase in the as-fabricated composites are collected and the Raman shift Δλ2 is measured; (3) the effective Raman shift Δλc can be calculated as Δλc = Δλ2−Δλ1. Therefore, the Δλc is the Raman shift totally induced by the matrix formation of the composites. To eliminate the Raman shift caused by high temperature, the as-coated interphases were also heat-treated at the same temperatures as the matrix fabrication. The characteristic peak at 1365 cm-1 is used as the reference stress-free peak for the interphase. This peak corresponds to the E2g mode peak and is strongly dependent on the crystallographic structure of BN. A slight variation of crystallographic parameters can lead to significant shift of E2g mode peak. Therefore, peak shifts (Δλ) relative to 1365 cm-1 are used to calculate the interfacial residual stress σr based on the linear formula σr = C × Δλ. 

2. 3 Mechanical test and microstructure characterization

To investigate the effects of interfacial residual stress on the mechanical behavior of the composites, tensile tests were performed on the composites with a mechanical testing machine (DDL20, Changchun Research Institute for Mechanical Science Co., Ltd., Changchun, China) following standard ASTM C1275. The tensile span is 45 mm and the loading rate is 0.5 mm/min. For each group of the composites, at least five samples were tested and the reported mechanical strengths were the averaged values. Cross-sectional and fracture morphologies of the composites were observed using an SU8220 field emission scanning electron microscope (Hitachi, Tokyo, Japan). Topographic images of the as-coated interphases were recorded with an atomic force microscope (AFM; SPA400/SPI3800N, Seiko Inc., Japan) operated in an amplitude-modulation mode using Si as the cantilever (Micro Masch, NSC12-B, Estonia). The surficial roughness of the interphases was calculated statistically based on the topographic height of the interphase using Image Analysis software. Furthermore, the shear modulus of the interphases was measured according to the force/distance curves obtained from AFM probe (Derjaguin–Muller–Toporov, DMT model). 

3 Results and discussion 

For multiple-phase ceramic composites fabricated at high temperatures, residual stress in the constituents evolves due to the mismatch of thermal expansion. Presuming that SiCf/SiC composites are an assembly of uniformly distributed SiC fiber, SiC matrix, and BN interphase existing between the fiber and the matrix, then the interfacial residual stress can be calculated based on the following classical equations [27,28]

where σi–f is the residual stress caused by the thermal mismatch between the interphase (i) and the fiber (f), and σi–m is the residual stress caused by the thermal mismatch between the interphase (i) and the matrix (m). Both the residual stresses can be expressed as a function of the difference between processing and ambient temperature (ΔT), thermal expansion coefficient (α), elastic modulus (E), Poisson’s ratio (υ), and the volume fraction (V) of the constituents. Then the interfacial residual stress (σr) can be calculated as a weighted sum of σi–f and σi–m based on the volume fraction of the constituents: 

Substituting the thermo-mechanical parameters of the constituents into the above equations (most of the parameters are drawn from published literature and summarized in Table 1), then σi–f, σi–m, and σr can be expressed as below:

Table 1 Thermal and mechanical properties of BN interphase, SiC fiber, and SiC matrix 

Then relationship of σi–f, σi–m, and σr versus processing temperature can be plotted as Fig. 1. All the residual stresses linearly increase with the temperature, and the σi–f is a little higher than σi–m, indicating that the fiber accounts more than the matrix in the formation of interfacial residual stress. As the SiCf/SiC composites were prepared at 1500–1650 ℃, the interfacial residual stress (σr) is ~40 MPa. However, as the residual stress calculation only considers the thermal expansion mismatch, the actual residual stress may be higher due to the pressure applied in the preparation process. 

Fig. 1 Interfacial residual stress of SiCf/SiC calculated from thermal expansion mismatch.

Raman is an effective technique to measure residual stress by correlating the residual stress with Raman peak shift. As the composites were prepared at high temperatures, in order to assure that the measured Raman shift is resulted from residual stress, not from heat-induced microstructure evolution, two strategies are adopted to calibrate the measurement. First, the microstructures of the interphase at RT–1650 ℃ are contrasted so as to eliminate the possibility that microstructural factors dominate the Raman shift. Second, the Raman shift of the interphase after the matrix formation is calibrated by that before the matrix formation, so the calibrated Raman shift can be considered to be totally induced by the residual stress generated during the matrix formation. 

The microstructure images (Figs. 2(a) and 2(b)) indicate that the as-coated interphase is uniformly coated on the fiber surface. The surficial morphology of the interphase is granular, with a granule size of ~500 nm. The cross-sectional morphology of the interphase (~600 nm in thickness) is characteristic of layered structure and the sublayer is ~20 nm in thickness. As the interphase is heat-treated at 1550 and 1650 ℃, the surficial granule size (~500 nm) almost remains the same with that of the untreated interphase (Figs. 2(c)–2(e)), indicating that the interphase remains thermally stable during the high-temperature processing. This can be further confirmed by the statistical results of the surficial roughness (Ra), as shown in Figs. 2(f)–2(h). The Ra values of the interphase surfaces (corresponding to green line in Figs. 2(c)–2(e)) are ~21–22 nm. The thermally stable interphase makes Raman spectroscopy a feasible tool to measure the residual stress of SiCf/SiC composites that fabricated at high temperatures.

Fig. 2 (a, b) SEM images of as-coated BN interphase on SiC fiber surface, (c–e) AFM images of the interphase at RT, 1550, and 1650 ℃, and (f–h) surficial roughness of the interphase.

The cross-sectional morphologies (Figs. 3(a) and 3(b)) of the as-received SiCf/SiC composites (fabricated at 1500 ℃) show that the reinforcing fibers are surrounded uniformly by a dense SiC matrix. The BN interphase remains intact and bonds tightly with the fibers and the matrix. Considering their different thermal expansion coefficients, there must be significant residual stress in the interphase. To investigate the variation of residual stress with the fabrication temperature, four groups of SiCf/SiC composites fabricated at 1500, 1550, 1600, and 1650 ℃ are used for the determination of residual stress. The Raman spectra of the interphases as-coated on the fiber surface and within the as-fabricated composites are shown in Fig. 3(c). For the purpose of calibration, the as-coated interphases were heat-treated at the same temperatures as the matrix fabrication. All the spectra show a sharp and strong peak at ~1365 cm-1, which corresponds to the in-plane vibration of BN phase [34,35]. The in-plane vibration has proved to be highly sensitive to the residual stress in the phase, and a certain amount of vibration peak shift represents a proportional residual stress in the phase [36]. The Raman results show that all the vibration peaks of the interphases show a negative shift relative to the characteristic peak position of BN phase at stress-free state (~1365 cm-1). As some chemical factors may also cause Raman shift, the Raman shift must be calibrated to determinate the residual stress. 

Fig. 3 (a, b) SEM images of the as-fabricated SiCf/SiC and (c) selected-area Raman spectra of the BN interphases as-coated on SiC fiber surface and within the SiCf/SiC. 

The calibration of Raman shift should consider two chemical factors. First, the CVD-derived BN interphase has some distinct microstructure features (Figs. 2(a) and 2(b)) compared with standard BN phase. Second, the high-temperature conditions of the matrix formation may induce atom diffusion/rearrangement in the interphase. Both these two factors can contribute to Raman shift. By subjecting the as-coated interphase to heat-treatment at the same temperatures as that of the matrix fabrication, the Raman shifts caused by the above factors are approximately the same for the as-coated interphase and the interphase within the composites. Therefore, the calibrated Raman shift (Δλc) can be obtained by subtracting the Raman shift of the as-coated interphase from that of the interphase in the composites (Fig. 4): 

where Δλ1 and Δλ2 denote the Raman shifts of as-coated interphase and the interphase within the composites, respectively. Then the interfacial residual stress (σr) in the composites can be calculated as below: 

where C is the conversion factor of Raman shift to residual stress. For BN phase, C is a constant of −0.2950 [36–38]. The negative valve of C indicates that a negative Raman shift in BN phase represents a positive σr value, i.e., tensile residual stress generated in the phase. 

Fig. 4 Schematic of calibrating Raman shift in the BN interphase. 

The variations of the Raman shift (Δλc) and the interfacial residual stress (σr) versus the fabrication temperature are shown in Fig. 5(a). As the fabrication temperature increases from 1500 to 1650 ℃, the Δλc of the interphase decreases from −0.09 to −0.28 cm-1. Correspondingly, the σr increases from 26.5 to 82.6 MPa in tension. Compared with the calculated results based on thermal expansion mismatch (Fig. 1), the Raman-measured σr is significantly higher when the temperature exceeding 1600 ℃. Especially at 1650 ℃, the measured σr is almost twice the calculated σr. As mentioned before, the calculated σr is obtained based on the thermal expansion mismatch without considering the pressure applied during the fabrication; therefore, the calculated σr should be underestimated. As both the fiber and the matrix have a higher thermal expansion coefficient than the interphase (Table 1), the formers expand more than the latter during the composite fabrication. Especially along the fiber axial direction, the expansion of the fibers is rather remarkable due to their extremely high length–diameter ratio (Fig. 5(b)). This subjects the interphase to residual tensile stress along the fiber axial direction. 

Fig. 5 (a) Raman shift and interfacial residual stress as a function of temperature and (b) schematic of interfacial residual stress in the SiCf/SiC. 

For SiCf/SiC composites, the interphase decides the mechanical behavior by tailoring the bonding strength between the fiber and the matrix. The residual stress in the interphase may change the bonding strength and thus exerts significant influence on the overall mechanical properties of the composites. In order to investigate the effects of residual stress on the mechanical properties, tensile mechanical tests were performed on the composites with various residual stresses in the interphase. The tensile stress–strain curves are shown in Fig. 6 and the mechanical properties are summarized in Table 2. All the composites show non-brittle fracture behaviors, with tensile strength ~200 MPa and tensile strain ~0.40%. As the interfacial residual stress increases from 26.5 to 64.9 MPa, the tensile strength increases from 171 to 238 MPa, and the tensile strain from 0.33% to 0.45%. However, as the residual stress reaches to 82.6 MPa, both the tensile strength and the tensile strain decrease significantly, declining to 184 MPa and 0.36%, respectively. The variation of mechanical properties indicates that the interfacial residual stress has significant effects on the mechanical behavior of the composites. The residual stress may induce different fiber/matrix debonding modes and thus contribute to the different mechanical properties. The effects of the residual stress can be further confirmed by the fracture microstructures of the composites. 

Fig. 6 Tensile stress–strain curves of the SiCf/SiC with various interfacial residual stresses. 

Table 2 Mechanical properties of the SiCf/SiC with various interfacial residual stresses 

The fracture surfaces of the composites show that with the interfacial residual stress increasing from 26.5 to 64.9 MPa the composites show prolonging length of fiber pull-out (Figs. 7(a), 7(c), and 7(e)), which coincides with the increasing tensile strain in the composites (Table 2). This may indicate that the increasing residual stress can facilitate the fiber/matrix debonding. For fiber-reinforced composites, different fiber/matrix debonding modes can lead to rather different fracture behaviors. In terms of where debonding occurs, the debonding of SiCf/SiC can be divided into i/f type and i/i type. For i/f type, the debonding occurs at interphase/fiber interface, while for i/i type, the debonding occurs within the interphase. As the residual stress increases from 26.5 to 64.9 MPa, the debonding mode transforms from i/f type to i/i type (Figs. 7(b), 7(d), and 7(f)). As the residual stress further increases to 82.6 MPa, the length of fiber pull-out decreases significantly (Fig. 7(g)). Although the debonding is still an i/i type, the interphase is delaminated drastically and peeled from the fiber (Fig. 7(h)). This indicates low shear strength of the interphase and thus low bonding strength of fiber/matrix. The low bonding strength can prevent stress transferring from the matrix to the fibers, thus inhibiting the reinforcing effect of the fibers. Therefore, the composites (Com-4) show a significant decrease in tensile strength and tensile strain compared with Com-2 and Com-3. 

Fig. 7 SEM images of the fracture surfaces of SiCf/SiC with various interfacial residual stresses. 

In general, fiber/matrix debonding mode of fiberreinforced composites is mainly dependent on the shear characteristics of interphase. The residual stress in the interphase may change the shear characteristics, thus leading to the different debonding modes in the composites. The effects of the residual stress on the shear characteristics can be shown in Fig. 8. Due to the different thermal/mechanical properties between the fiber and matrix, the interfacial residual stress is inhomogeneous across the thickness of the interphase, and the residual stress close to the fiber is higher than that close to the matrix (which is deduced by higher σi–f than σi–m in Fig. 1). From the view of mechanics, the inhomogeneous residual stress can be equivalent to residual shear stress across the thickness of the interphase (Fig. 8(a)). The residual shear stress can facilitate sublayer shear slipping in the interphase, and thus weaken the shear strength of the interphase. To quantitatively investigate the shear property of the interphase, indentation testing was performed on the interphase using an AFM probe. During the indentation, the force vs. distance curve is recorded and then the shear modulus of the interphase is obtained based on the curve slope (Fig. 8(b)). As the interfacial residual stress increases from 26.5 to 82.6 MPa, the shear modulus of the interphase decreases from 22.9 to 19.5 GPa (Fig. 8(c)). This confirms that the residual stress can degrade the shear strength of the interphase and thus facilitate sublayer slipping in the interphase. At low residual stress, the moderate sublayer slipping in the interphase can strengthen the reinforcing effect of fiber by promoting fiber/matrix debonding, which leads to improvement of mechanical properties. However, high residual stress can lead to immoderate sublayer slipping. The immoderate sublayer slipping can lead to significant delamination in the interphase, which degrades the reinforcing effect of fiber and thus worsens the mechanical properties of the composites. 

Fig. 8 Effects of the interfacial residual stress on the shear modulus of the BN interphase: (a) inhomogeneous distribution of the interfacial residual stress, (b) indentation testing on the interphase using an AFM probe, and (c) shear modulus of the interphase versus the interfacial residual stress. 

Therefore, the effects of interfacial residual stress on the mechanical behavior of the composites can be illustrated in Fig. 9. The residual stress can lead to fiber/matrix debonding within the interphase by inducing sublayer slipping in the interphase. As the residual stress is low, the debonding preferentially occurs at interphase/fiber interface. However, increasing the residual stress can lead to i/i debonding, where the debonding occurs within the interphase. Benefiting from the enhanced fiber pull-out of i/i debonding, both mechanical strength and strain of the composites are improved. Furthermore, with the residual stress increasing up to a certain threshold, the interphase is delaminated presumably due to its immoderate sublayer slipping. The delaminated interphase can suppress stress transferring from the matrix to the fiber, resulting in deteriorating mechanical properties. Actually, the effects of the residual stress on the mechanical behavior should consider the intrinsic characteristics of the composites, such as chemical composition, fiber fabric, and preparation condition. Therefore, the overall understanding of residual stress in the composites still needs more researches. Nevertheless, this study promotes the research by providing a method for determining the residual stress in the interphase and revealing its effects on the mechanical behavior of the composites. 

Fig. 9 Schematic of fiber/matrix debonding transformation in SiCf/SiC under increasing interfacial residual stress. 

4 Conclusions 

In present study, the interfacial residual stress of SiC fiber-reinforced SiC matrix (SiCf/SiC) composites was investigated using a micro-Raman spectrometer. The residual stress was measured based on the Raman shift of the BN interphase. It was found that the residual stress increases from 26.5 to 82.6 MPa as the fabrication temperature of the composites rises from 1500 to 1650 ℃. The residual stress is tensile with direction parallel to the fiber axis, and found to exert significant influence on the mechanical properties of the composites. The increasing residual stress can improve the tensile strength of the composites from 171 to 238 MPa. The transformation of fiber/matrix debonding from i/f type to i/i type induced by the residual stress should be responsible for the improvement of the mechanical properties. However, with the residual stress increasing up to 82.6 MPa, the mechanical properties of the composites degrade remarkably due to the delamination of the interphase. This work provides a feasible alternative for determination of interfacial residual stress in fiber-reinforced ceramic composites, and offers new insight for the relationship between the residual stress and the mechanical behavior of the composites. 

References: omitted

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