SiC whisker reinforced MoSi2 composite prepared by spark plasma sintering from COSHS-ed powder
XU Jian-guang(许剑光)1, 2, ZHANG Hou-an(张厚安)1, JIANG Guo-jian(江国健)2
ZHANG Bao-lin(张宝林)2, LI Wen-lan(李文兰)2
1. Institute of Material Surface Engineering, Hunan University of Science and Technology, Xiangtan 411201, China;
2. Shanghai Institute of Ceramics, Chinese Academy of Sciences, Shanghai 200050, China
Received 10 April 2006; accepted 25 April 2006
Abstract: SiC whisker reinforced MoSi2 composite powder was synthesized by a novel process, referred to the literature as chemical oven self-propagating high temperature synthesis(COSHS). The as-prepared SiCw/MoSi2 composite powder was rapidly sintered by spark plasma sintering(SPS) process. The sintering temperature and pressure were 1 723 K at heating rate of 100 K/min and 40 MPa, respectively. The microstructure and mechanical properties of the composite were investigated. Relative densities of the monolithic material and composite are 95% and 99.3%, respectively. SEM micrographs of SiCw/MoSi2 composite show that SiC whiskers homogeneously distribute in MoSi2 matrix. The composite containing SiC whisker has higher Vicker hardness than monolithic MoSi2. Especially the room-temperature fracture toughness of the composite is higher than that of MoSi2, from 3.6 MPa ?m1/2 for MoSi2 to 7.7 MPa?m1/2 for composite with 15% SiC(volume fraction), increased by 113.9%. The morphology of propagation of crack and fractured surface of composite reveal the mechnaism to improve fracture toughness of MoSi2 matrix. The results show that the in-situ SiCw/MoSi2 composite powder prepared by COSHS technique can be successfully sinterded through SPS process and significant improvement of low temperature fracture toughness can be achieved.
Key words: MoSi2; SiC whisker; composite materials; spark plasma sintering; chmical oven
1 Introduction
MoSi2 has attracted great research interest due to its rather low density, high melting point, high electrical conductivity and very good oxidation resistance at high temperature[1-4]. It is useful in such applications as high temperature heating elements and possible structural parts at elevated temperature. However, monolithic MoSi2 exhibits extreme brittleness and poor impact strength at lower temperature, and has low strength and creep resistance at elevated temperature (>
1 200 ℃). Thus, it is essential to increase the room temperature fracture toughness, high temperature strength and creep resistance. Some significant improvements have been obtained through the addition of SiC whiskers or particles to MoSi2 matrix[3,5-20]. And the mechanical properties of SiC whiskers reinforced MoSi2 composite are better than SiC particles reinforced MoSi2 composite[3,7-9]. Therefore, SiC whisker-reinforced MoSi2 composites are considered as excellent candidates for high temperature applications.
Although numerous attempts to introduce artificial SiC phase into MoSi2 have been made, only a limited number of studies have addressed their introduction via in situ reactions, and these studies only focus on the introduction of SiC particles[10-17]. These reactions offer the possibilities of generating stable second-phase dispersions in addition to eliminating undesirable interface between the second phase and matrix during processing. The interface between the particles and matrix is often a potential source of weakness owing to the very different thermal expansion coefficient.
Combustion synthesis, or self-propagating high temperature synthesis(SHS) is a technique for producing ceramics, intermetallic and composite materials. The advantage in the SHS process lies in its low cost, in the ability to form powders with very unluckily, these studies only focus on SiC particles reinforced MoSi2 composite powders[18-20]. There are two reasons. Firstly, the form introduction of SiC whiskers in MoSi2 matrix is a problem. Secondly, for the case of some systems, such as MoSi2-SiC, ignition is impossible without addition activation. Primarily this is due to the thermodynamic limitation, i.e. a low reaction enthalpy or the relatively low adiabatic combustion temperature of these systems.
Recently, a novel process, referred to in the literature as chemical oven SHS (COSHS)[21] was developed to prepare some powders that cannot be obtained through conventional SHS. In the COSHS mode of combustion, the reactant pellet outside is ignited at upper surface by a high-energy heat input and layerwise combustion occurs at a definite rate of wave propagation. The reactant pellet inside is warmed up by the heat given out from the reaction outside and then ignited at the bottom surface contacted with the reactant outside. Because of the increased reaction temperature and long-time at high temperature, the reaction is carried out thoroughly and impurities are evaporated completely. In this work, SiC whiskers reinforced MoSi2 composite powders were produced from the mixing powders of Mo, Si, carbon black and Si3N4 whiskers via COSHS process. The bulk of this paper will discuss the mechanical properties of composite made from COSHSed Powder, consolidated by spark plasma sintering (SPS).
2 Experimental
98.5% pure Mo powder with a particle size range of 2-5 mm , 99.4% pure Si powder with an average size of 10 mm and 99.9% pure carbon black with an average size of 6 mm. are used as starting raw materials in this study. The Si3N4 whiskers were obtained from our research group by SHS process[22]. The microstructure of Si3N4 whiskers is shown in Fig.1. The sample was prepared according to the composition of 15% SiC. The mixture was combusted via COSHS process in a steel chamber under 0.5 MPa Ar (99.9%, mass fraction) pressure. For sintering studies, the as synthesized fragile mass was milled for 10 min in a ball mill. The details of the COSHS technique for the in-situ SiCw/MoSi2 powder preparation have been published elsewhere.
To form a sample, the milled powder was compacted to green-body cylinders of about 10 mm diameter and 2 mm height. The latter was then put into a carbon die (10 mm inner diameter) lined with graphite foil, followed by introduced into SPS apparatus and consolidation through SPS procedures. The sintering conditions were as follows: 1) A pressure of 40 MPa was applied at the beginning of the sintering process and released during the cooling portion of a complete sintering cycle; 2) The sintering temperature was at
Fig.1 SEM micrograph of Si3N4 whiskers
1 723 K, and the heating rate was 100 K/min; 3) The holding time at sintering temperature was 5 min.
After sinering, the sample was removed from the dies and lightly ground to remove the graphite foil. Sample was polished on SiC paper and then diamond for microscopic examination.
The morphologie of sintered product was studied by using scanning electron microscopy (SEM) with an energy dispersive X-ray spectrometer (EDS). Sintered sample density was measured by the Archimedes method. The Vickers hardness (HV) and fracture toughness (KIc) were measured on polished specimen using Vicker’s diamond indentor under 98 N for 15 s. KIc value was calculated by using the equation reported by ANSTIS et al [23].
3 Results and discussion
3.1 Microstructure
The XRD result shows that the as-prepared powder is mainly composed of MoSi2 and SiC phases. Besides the mainly two phases, trace Mo4.8Si3C0.6 (Nowotny phase) also can be observed. The SEM photo and EDS result show that SiC whisker is formed during this COSHS process. The results of as-prepared powder by COSHS technique have been published elsewhere.
The SEM micrographs of polished surface and fractured surface of SiCw/MoSi2 are shown in Fig.2 and Fig.3, respectively. In Fig.2, besides the bright matrix phase, there is a black rodlike phase. Semi-quantitative analysis (EDS) shows that it consists of C (41.7 %, mole fraction, the same below), Si (53.5%) and Mo (4.5%). This could probably be SiC whisker. From Fig.2, it can be observed that SiC whiskers are homogeneously distributed in MoSi2 matrix from both the polished surface and fractured surface.
Fig.2 Propagation of crack in polished surface of SiCw/MoSi2 composite
3.2 Mechanical properties
The mechanical properties of fabricated composites are given in Table 1. For comparison, the mechanical properties of monolithic MoSi2 are also listed in Table 1. The relative density of both materials is high, up to 99.3%. It is shown that high-density MoSi2 could be obtained at lower sintering temperatures for shorter sintering time by SPS than hot press. Significant improvement in Vicker’s hardness has been obtained by incorporation SiC whisker into MoSi2. This may be due to the high hardness of SiC over that of MoSi2. Table 1 also shows fracture toughness results at room temperature of SiCw/MoSi2 composite and monolithic MoSi2. The fracture toughness result of SiCw/MoSi2 composite is 7.7 MPa·m1/2, increased by approximately 113.9% as compared to MoSi2 matrix. The result is also better than the result of 20%(volume fraction) SiCw/MoSi2 [9] by artificial process, because undesirable interface between second phase and matrix can be eliminated via in situ process. It can be concluded that the addition of SiC whiskers via in situ process significantly improved the fracture resistance of the MoSi2.
Table 1 Mechanical properties of sintered products
Fig.3 and Fig.4 show the fractured surface of SiCw/MoSi2 composite and monolithic MoSi2, respectively. It can be clearly observed from Fig.3 and Fig.4 that MoSi2 grain size of SiCw/MoSi2 is smaller than monolithic MoSi2, which is benefit to the improvement of fracture toughness.
Fig.2 shows the propagation of crack in the polished surface of SiCw/MoSi2 composite. With the existence of SiC whiskers in MoSi2 matrix, clear deflection of crack by tilting and twisting around SiC whiskers is observed. This results in the fracture surface that contains holes and mounds in regions in which deflection occurs continuously by tilting around the SiC whiskers (Fig.3). The deflection of crack would lead to the increase of fracture toughness. And it is also observed that the whiskers bridge the crack in Fig.2. Furthermore, holes and outcrops of whiskers by pullout can be seen from the fractured surface in Fig.3. Consequently, the traction force of bridging whiskers could efficiently stop the propagation of crack and enhance the fracture toughness.
Fig.3 SEM micrograph of fractured surface of SiCw/MoSi2 composite
Fig.4 SEM micrograph of fractured surface of MoSi2
4 Conclusions
SiC whisker reinforced MoSi2 composite has been successfully fabricated by spark plasma sintering (SPS) from “chemical oven” combustion synthesized powder. Increased microhardness, fracture toughness are achieved by the introduction SiC whiskers into MoSi2 matrix. Particle size decreases, cracks deflection and whiskers pullout and bridging are probable mechanism responsible for this behavior.
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(Edited by LONG Huai-zhong)
Foundation item: Project (50232020) supported by the National Natural Science Foundation of China
Corresponding author: XU Jian-guang; Tel: +86-732-8290043-807; Fax: +86-732-8290544; E-mail: jgxu@163.com
