Abstract
In situ HfB2–SiC–VSi2 composite was fabricated by reactive pressureless sintering at the temperature of 2150 °C for 4 h under a vacuum atmosphere. In situ SiC and VSi2 reinforcements were formed using VC and Si powders as starting materials according to the following reaction: VC + 3Si = SiC + VSi2. Microstructural studies and thermodynamic calculations revealed that in situ VSi2 and SiC phases were mostly formed and homogeneously distributed in HfB2 skeleton. The results showed that the density of in situ HfB2–SiC–VSi2 composite was 98%. Besides, the mechanical properties of the composite were effectively enhanced by the formation of in situ second phases. The Vickers hardness and the fracture toughness of the composite reached 20.1 GPa and 5.8 MPa m−1/2, respectively.
Similar content being viewed by others
Introduction
Advanced ceramics and protective coatings for high temperature applications have been recently attracted1,2,3,4,5,6,7,8,9,10,11. With a high melting point (about 3380 °C), high thermal and electrical conductivity, excellent strength at the severe environment, and brilliant thermal shock resistance, HfB2 is one of the ultra-high temperature ceramics (UHTCs). Due to its excellent properties, it has been considered for high-temperature applications such as nose cone and the leading edge of hypersonic flight vehicles and advanced rocket motors12,13,14. Recently, many studies have been undertaken to densify HfB215,16,17. Because of the low self-diffusion coefficients and tightly covalent bonding, generally, pressure-assisted methods such as Spark plasma sintering (SPS), and Hot pressing (HP) are applied for consolidation of HfB2-based composites. However, using these methods restrict geometrical dimensions, especially for complex-shaped specimens. Reactive pressureless sintering is one of the practical methods to fabricate near-net-shape HfB2-based composites where matrix or reinforcement phases are in situ formed.
Brochu et al.18 densified ZrB2 ceramic by reactive pressureless sintering method using Zr and B powders as starting materials. However, they did not use any additive for the densification of ZrB2; the maximum density was reported about 79% for monolithic ZrB2.
Wang et al.19 reported the relative density of 97.2% for B4C–SiC–TiB2 composite fabricated by reactive pressureless sintering method.
Zhang et al.20 fabricated Ta0.8Hf0.2C–SiC composite using HfSi2, TaC, and carbon black powders by reactive pressureless sintering method at 2200 °C. The relative density of the composite was reported about 99%.
It has been reported that the oxide impurities (HfO2, B2O3) of HfB2 starting powder can prevent the densification of HfB2 ceramic21. Therefore, removing the oxide impurities and reaching full dense HfB2-based composites has been a challenging issue for researchers. Some additives or reinforcements have been suggested to enhance the sinterability and mechanical properties of UHTCs. In an attempt to increase the sintered density of UHTC-based composites, some researchers used oxide and non-oxide additives such as Y2O322, Ta23, Al24, TaSi225, and MoSi226. Among them, SiC is an additive that has been commonly used due to its capability to improve the mechanical properties as well as the oxidation resistance of transition metal borides27,28. Moreover, silicides have been added to HfB2 to improve its mechanical properties owing to such superior properties as excellent creep resistance and oxidation behavior.
The addition of VSi2 for enhancing properties of UHTC is a novel idea. However, the sintering process of HfB2 ceramic with other silicides has been accomplished by other researchers. For example, Sciti et al.25 densified UHTC-based composites containing 3 vol% silicides of molybdenum or tantalum as sintering additives. They have reached the fracture toughness of 5.1 MPa m1/2 for the HfB2–TaSi2 composites as well as 4.4 MPa m1/2 for the HfB2–MoSi2 composites. In other research, Zhang et al.29 fabricated ZrB2–WSi2 composite via hot pressing method. They reported the fracture toughness of 3.5 MPa m1/2 for the composite. SiC and VSi2 could be suitable additives for HfB2-based composites, due to their low density, high thermal conductivity, and excellent oxidation and creep resistance30,31.
The aim of this work is the fabrication and properties evaluation of HfB2–SiC–VSi2 composite which is fabricated by HfB2, VC, and Si powders via reactive pressureless sintering method. We investigate the effect of in situ VSi2 and SiC phases on the densification, microstructure, and mechanical properties of HfB2–SiC–VSi2 composite.
Experimental methods
In order to fabricate the HfB2–15 vol%SiC–15vol%VSi2 composite, the commercial HfB2, VC, and Si powders were used as starting materials. The characteristics of starting powders are listed in Table 1. Calculations of volume fractions were performed to define the composition of the composite. The powders were milled by a high-energy planetary mill for 5 h in ethanol medium. WC–Co cup and balls were selected and a speed ratio of the milling process was defined 300 rpm. The weight ratio of powders to balls was determined 1:3. For removing ethanol from mixed powders, the drying process was accomplished for 24 h in air. Cylindrical specimens (Φ25 × 8 mm2) without any binders were cold-pressed by uniaxial pressing at 50 MPa and then were cold isostatically pressed at 300 MPa. Reactive pressureless sintering process was performed in a commercial graphite resistance heating furnace at 2150 °C for 4 h under a vacuum atmosphere of 0.05 mbar. For completing the formation of in situ phases, a heating rate was decreased from 1150 to 1350 °C according to the reaction (3). Table 2 shows the main features and the sintering conditions for the sintered composite.
Before the sintering process, the green density of the composite was measured by the ratio between the mass and the volume of the sintered specimens according to dimensional measurements. It should be noted that the relative green density was reported by the ratio between green and theoretical densities. The theoretical density of the composite was calculated based on the final composition after the sintering process (see Sect. Densification and microstructure and Fig. 2) by the rule of mixture according to theoretical densities of 11.2 g/cm3 for HfB2, 3.2 g/cm3 for SiC, 4.42 g/cm3 for VSi2, and 12.2 g/cm3 for HfC. The bulk density of sintered samples was measured using Archimedes method. Hence, the relative density of the sintered specimens was reported by the ratio between the bulk and theoretical densities. Young's modulus was determined through ultrasonic testing at 25 °C according to the ASTM C119832 by sound velocity using the TC600 model thickness measuring apparatus. The Vickers hardness test was carried out on the polished surfaces of the sintered specimens by a Vickers indenter with 0.3 kg applied load for 10 s33:
where Hv is the Vickers hardness (GPa), P refers to the applied force for indentation (N), and d means the average diagonal length of indent (m).
The fracture toughness of the sintered specimens was calculated using Evans and Charles’s equation34:
where \(KIC\) refers to the fracture toughness (MPa m−1/2), H means Vickers hardness (GPa), c is the average half-length of the crack acquired in the tips of the Vickers marks (m), and a is the average half-length of indentation diagonal (m). The fracture toughness was evaluated by the applied load of 20 kg.
To the accuracy of the result, five specimens for HfB2–SiC–VSi2 composite were tested and ten measurements were repeated for each specimen. Moreover, the microstructural observation was examined on the mirror-like surfaces of sintered specimens by field emission scanning electron microscope (FESEM, TESCAN, Model: MIRA3) equipped with energy-dispersive spectroscopy (EDS). Besides, to ensure reliable results, the microstructural analysis was done on different parts of the specimens. The phase composition was determined by X-ray diffraction analysis (XRD, Philips, Model: X’Pert MPD, Tube: Co, and λ: 1.78897 Å). The grain size of the sintered composite was estimated by the image analysis (ImageJ software). To determine the possibility of in situ formations of phases during the sintering process, thermodynamic calculations were performed using HSC software. The final composition after sintering was calculated by ImageJ analyzing software. For this purpose, ten random images of SEM micrographs at different magnifications were selected and evaluated.
Result and discussion
Densification and microstructure
The relative green and relative densities of reactive pressureless sintered HfB2–SiC–VSi2 composite are presented in Table 2. The relative density of the composite reached 98%. FESEM image of the microstructure of the pressureless sintered composite is shown in Fig. 1. It has been reported that diffusion rate and porosity mobility are enhanced by increasing the sintering temperature which finally causes the reduction of cavities in the sintered composite35. The very small amount of porosity is observed in the microstructure after the sintering process which confirms that the temperature of the sintering process (~ 2150 °C) was adequate to remove most of the porosities. On the other hand, the mobility of the grain boundary of HfB2 was decreased by in situ formations of SiC and VSi2 phases alongside HfB2 grains. The average HfB2 grain size was estimated about 10 µm. Some ultra-fine grains inside HfB2 phase could be found and EDS analysis revealed them to be VSi2. Due to the 1677 °C melting point of VSi2, it seems that the VSi2 was molten during the sintering process. The molten VSi2 flowed through the capillaries and filled the pores. Based on this scenario, these ultra-fine grains were recrystallized VSi2 which were located at pores and finally led to an improvement in the density of the composite. Aside from VSi2 phase, three regions are distinguished in the microstructure of the composite. Black regions are SiC, white regions are HfC, and the light regions are HfB2 according to EDS analysis. This result is in excellent agreement with the previous study of the fabrication of in situ HfB2-based composites21.
Figure 2 shows the final composition of the composite after the sintering process. The final composition of the composite was estimated HfB2–10.3%SiC–20.52%VSi2–15.75%HfC by image analysis which is close to the target composition.
Mechanical properties
The values of the Vickers hardness, the elastic modulus, and the fracture toughness of the composite are listed in Table 2. Owning to the hardness value of SiC (~ 27 GPa)36 and HfC (~ 28 GPa)37, the average hardness of the reactive pressureless sintered composite reached 20.1 GPa. However, the hardness value of VSi2 is lower than HfB2 matrix; in situ VSi2 phase formation improved the hardness by promoting the elimination of porosities.
Sonber et al.38 fabricated HfB2–TiSi2 composite by hot pressing method. They reported the hardness value of 11.5 GPa for monolithic HfB2 and 25.4 GPa for HfB2–TiSi2 composite.
Ghadami et al.21 demonstrated that the Vickers hardness of HfB2-based composite improves with the in situ formation of SiC and MoSi2 during sintering. They reported the hardness value of 18 GPa for monolithic HfB2 and 25.2 GPa for HfB2–SiC–MoSi2 composite. Improvement of density by the formation in situ phases as well as the inherent hardness of in situ phases contributed to the desirable Vickers hardness of the composite.
Young’s modulus of the composite was 401.3 GPa in which was close to the estimated Young’s modulus using the role of mixture (about 424.7 GPa). According to Fig. 3, to evaluate the fracture toughness of the composite, the average half-length of the cracks was measured 45 μm and the average half-length of indentation diagonal was measured 108 μm.
The fracture toughness of the composite was measured to be 5.8 MPa m−1/2 which was noticeably higher than those of the reported HfB2-based composites in the range of 3.5–3.9 MPa m−1/239,40. The main reason for desirable fracture toughness was attributed to increasing obstacles for crack propagation by in situ formations of VSi2 and SiC. HfB2 large grain size (~ 10 μm) could also increase the fracture toughness. Figure 4 shows the crack propagation in the microstructure of the composite.
Because of a significant mismatch between the thermal expansion coefficient of HfB2 (6.3 × 10−6 K−1)41, SiC (4.7 × 10−6 K−1)42, VSi2 (11.2–14.65 × 10−6 K−1)43, and HfC (6.6 × 10−6 K−1)44, some compressive stresses may be induced after the sintering process. Therefore, the SiC particles are under compressive stress. On the other side, HfB2 matrix is under tensile stress in a tangential direction as well as compressive stress in a radial direction. The compressive stress around SiC particles causes the crack is deflected. It should be concluded that the crack is deflected when the crack strikes SiC particle. SiC particle dissipates the energy of the crack resulting in enhancing the fracture toughness of the composite.
Hence, increasing compressive stresses around SiC particles enhanced the fracture toughness of HfB2–SiC–VSi2 composite. These results were supported by other researchers45,46,47,48,49.
In previous studies, the effective role of reinforcement morphology was demonstrated21,50.
The SiC particles were elongated and homogeneously distributed in the HfB2 skeleton.
Besides, in situ formations of needle-like SiC particles provided more obstacles against the crack propagation. Padture et al.51 reported that the elongated SiC grains enhance the fracture resistance by crack bridging and crack deflecting.
Figure 5 shows the interaction between in situ SiC particle and the crack. When the growth path of the crack tip strikes the SiC particle, three mechanisms may occur. First mechanism: the energy of the crack is not enough to break the SiC particle, but the crack has enough energy to change its growth direction. Therefore, the crack is deflected through the weaker direction (Fig. 5a). Second mechanism: in situ elongated SiC particle dissipates the crack energy by crack bridging mechanism (Fig. 5b). Third mechanism: SiC particle absorbs the whole energy of the crack and then the crack is pinned (Fig. 5c).
As a result, the formation of elongated α-SiC particles contributed to the favorable fracture toughness of the reactive pressureless sintered composite.
Figure 6 presents the fractured surface of the composite. As can be seen, in some areas the fracture surface is rough whereas in other areas the fracture surface is sharp and grains are pulled out. The sharp edges and pulled out grains prove that the crack propagates through the grain boundaries and leads to the inter-granular fracture mode. On the other side, the rough surfaces indicate that the grain boundaries are much more stronger than the inside of grains. The crack propagates through the inside of grains and leads to the intra-granular fracture mode.
This result proves that the fracture mode was mixed with inter- and intra-granular modes.
In situ formation of SiC and VSi2 reinforcement particles contributed to improving the strength of grain boundaries and finally enhanced the fracture toughness of the composite.
In situ phase formation
Figure 7 illustrates the diagram of reaction possibility between VC and Si which was simulated according to the sintering condition (~ 0.05 mbar) by HSC software. VC and Si could react with each other and produce VSi2 and SiC simultaneously. According to the thermodynamic calculations, VSi2 and SiC could be formed even at the room temperature and the reaction (3) could happen at the beginning stages of the sintering process as following:
However, it seems that the required kinetic energy for activation of the reaction (3) is not adequate at the initial temperatures. Ko et al.52 demonstrated that SiC and VSi2 could be formed at 1250 °C under argon atmosphere. Hence, the formation of SiC and VSi2 needs higher temperatures (at least 1250 °C).
On the other side, VSi2 and SiC decompose at 1350 °C and 1800 °C, respectively. However, the kinetic energy of the reverse direction of the reaction (3) is not sufficiently adequate. Hence, the decomposition of VSi2 and SiC did not take place under the present sintering conditions (see Sect. 3.1). It leads to the conclusion that in situ VSi2 and SiC phases could be mostly formed at 1250 °C with ∆G of − 92.793 kJ.
Shahedi Asl et al.53 reported that the reaction between VC and ZrB2 could be possible according to the following reaction:
Similarly, there is a chance to the reaction between HfB2 and VC as following:
To find out the possibility of the reaction between HfB2 and VC, thermodynamic calculations were performed for the reaction (5). Figure 8 illustrates the priority between reactions (3) and (5). With a larger negative delta G for the reaction (3), the reaction (3) is progressed predominantly. Therefore, the formation of VB2 and HfC phases from the reaction (5) is unlikely to happen. Back to the details of the reaction (3), SiC and VSi2 were completely formed at 1250 °C. In the temperature range of 1400–1700 °C delta G of this reaction was dramatically increased which indicated that a thermodynamic transformation could occur. It was reported that the melting points of SiC and VSi2 are to be 2830 °C and 1677 °C, respectively54,55. It seems that the endothermic transformation is related to the melting of VSi2. Based on this hypothesis, the melting process of VSi2 was thoroughly completed at 1700 °C. This result was supported by the extracted result from the microstructural study. Moreover, in situ HfC phase could be formed according to the following reaction:
The mass of the WC impurity from milling media was measured which indicated that ~ 5 wt%WC was incorporated into the mixed powders. It has been reported that the located HfO2 on the surface of HfB2 powders plays a barrier role against densification21. WC impurity from milling media could react with HfO2 from starting powder; hence, it could remove the oxide-impurity and finally enhance the sintering process.
Phase analysis
X-ray diffraction patterns of the mixed powders and the pressureless sintered composite are shown in Fig. 9. From this Fig. 9, HfB2, HfO2, VC, Si, WC phases were detected which indicate that HfO2 and WC impurities were present in the starting mixtures. Owing to WC–Co cup and balls, 5 wt%WC could be inserted by the milling process. Besides, HfB2 powder contained HfO2 impurity based on Table 1. On the other hand, HfB2, VSi2, SiC, and HfC phases were found and no obvious impurity phases can be seen after the sintering process. According to the reaction (6), it could be concluded that HfO2 and WC reacted to each other and produced HfC. This result is supported by other researchers56,57.
It has been reported that carbon could be penetrated from graphite mold to the structure of HfB2-based composite during the sintering process21,58. Penetrated carbon could react with HfO2 impurities at the temperature of 1700 °C according to the following reaction:
It should be noted that the reaction (7) as well as the reaction (6) could produce HfC. However, this work intended to fabricate HfB2-15vol% SiC-15 vol%VSi2 composite, based on the reactions (6 and 7), HfC could be formed and the final composition included HfC according to Fig. 2.
Moreover, no corresponding peaks of vanadium carbide and silicon were identified after the sintering process.
The presence of VSi2 and SiC peaks in Fig. 9 demonstrated that the reaction (3) was mostly completed. VB2 phase was not detected after the sintering process which indicated that the reaction (5) was not favorable. On the other side, HfC phase was possibly formed from the reactions (6 and 7) and less likely from the reaction (5). W phase from the reaction (6) was not detected by XRD analysis.
It seems that W atoms were hosted in HfB2 structure and led to the formation of (Hf, W)-B solid solution. However, detecting the negligible (Hf, W)-B solid solution needs to have more precise microstructural studies such as TEM technique. In this work, (Hf, W)-B solid solution was identified by EDS analysis as shown in Fig. 10. This hypothesis shows an excellent agreement with the reported result from other researchers56,59,60,61,62,63.
Finally, Fig. 11 schematically illustrates the sintering mechanism of HfB2–SiC–VSi2 composite during the sintering process up to 2150 °C. After the milling process, mixed powders including HfB2, Si, and VC are randomly distributed (Fig. 11a). During the sintering process, the reaction between Si and VC could happen at 1250 °C. Therefore, VSi2 and SiC are formed as byproducts from reaction (3). Similarly, HfC, W, and CO(g) are formed from reaction (6 and 7) (Fig. 11b). CO gas product can release from the skeleton when HfC remains in the microstructure of the composite. W atoms from reaction (6) are hosted in HfB2 structure and cause to the formation of (Hf, W)-B solid solution (Fig. 11c). VSi2 is melted at 1700 °C and then molten VSi2 flows through the capillaries and fills pores (Fig. 11d). Eventually, the microstructure consists of HfB2, VSi2, SiC, and HfC phases which distribute in the microstructure after the sintering process at 2150 °C (Fig. 11e).
Conclusions
HfB2–SiC–VSi2 composite was densified by reactive pressureless sintering using HfB2, VC, and Si as starting powders at 2150 °C under vacuum atmosphere (0.05 mbar) for 4 h. Microstructural investigations and XRD analysis showed that in situ SiC and VSi2 phases were formed during the sintering process and homogenously distributed in HfB2 skeleton. Moreover, HfO2 impurity was successfully removed and turned to HfC by reacting with inserted WC impurity from milling media. The relative density of the composite was measured by 98%. According to thermodynamic calculations performed by HSC software, VSi2 was melted at 1700 °C and filled pores which contributed to an increase in the relative density of the composite. The Young's modulus, Vickers hardness, and fracture toughness values of the composite were determined to be 401.3 GPa, 20.1 GPa, and 5.8 MPa m−1/2, respectively. The improvement of the mechanical properties of the sintered composite was attributed to the in situ formation of SiC and VSi2 phases.
References
Sohi, M. H. & Ghadami, F. Comparative tribological study of air plasma sprayed WC–12% Co coating versus conventional hard chromium electrodeposit. Tribol. Int. 43, 882–886 (2010).
Ghadami, F., Zakeri, A., Aghdam, A. S. R. & Tahmasebi, R. Structural characteristics and high-temperature oxidation behavior of HVOF sprayed nano-CeO2 reinforced NiCoCrAlY nanocomposite coatings. Surf. Coat. Technol. 373, 7–16 (2019).
Ghadami, F., Sohi, M. H. & Ghadami, S. Effect of TIG surface melting on structure and wear properties of air plasma-sprayed WC–Co coatings. Surf. Coat. Technol. 261, 108–113 (2015).
Ghadami, F., Aghdam, A. S. R., Ghadami, S. & Zeng, Q. Effect of vacuum heat treatment on the oxidation kinetics of freestanding nanostructured NiCoCrAlY coatings deposited by high-velocity oxy-fuel spraying. J. Vacuum Sci. Technol. A Vacuum Surfaces Films 38, 022601 (2020).
Ghadami, F. & Rouh Aghdam, A. S. Preparation of NiCrAlY/nano-CeO2 powder with the core-shell structure using high-velocity oxy-fuel spraying process. Mater. Chem. Phys. 243, 122551. https://doi.org/10.1016/j.matchemphys.2019.122551 (2020).
Ghadami, F., Ghadami, S. & Abdollah-Pour, H. Structural and oxidation behavior of atmospheric heat treated plasma sprayed WC–Co coatings. Vacuum 94, 64–68 (2013).
Ghadami, F., Aghdam, A. S. R., Zakeri, A., Saeedi, B. & Tahvili, P. Synergistic effect of CeO2 and Al2O3 nanoparticle dispersion on the oxidation behavior of MCrAlY coatings deposited by HVOF. Ceram. Int. 46, 4556–4567 (2020).
Ghadami, F., Aghdam, A. S. R. & Ghadami, S. Abrasive wear behavior of nano-ceria modified NiCoCrAlY coatings deposited by the high-velocity oxy-fuel process. Mater. Res. Express 6, 1250d1256 (2020).
Ghadami, F. & Aghdam, A. S. R. Improvement of high velocity oxy-fuel spray coatings by thermal post-treatments: A critical review. Thin Solid Films 678, 42–52 (2019).
Ghadami, F. & Aghdam, A. S. R. Preparation of NiCrAlY/nano-CeO2 powder with the core-shell structure using high-velocity oxy-fuel spraying process. Mater. Chem. Phys. 243, 122551 (2020).
Ghadami, S., Taheri-Nassaj, E., Baharvandi, H. R. & Ghadami, F. Effect of in situ SiC and MoSi2 phases on the oxidation behavior of HfB2-based composites. Ceram. Int. 46, 20299–20305 (2020).
Savino, R., Fumo, M. D. S., Silvestroni, L. & Sciti, D. Arc-jet testing on HfB2 and HfC-based ultra-high temperature ceramic materials. J. Eur. Ceram. Soc. 28, 1899–1907 (2008).
Zhang, G.-J., Guo, W.-M., Ni, D.-W. & Kan, Y.-M. Ultrahigh Temperature Ceramics (UHTCs) Based on ZrB2 and HfB2 Systems: Powder Synthesis, Densification and Mechanical Properties 012041 (IOP Publishing).
Seetala, N. V. & Webb, M. T. Spark Plasma Heat Treated ZrB2-SiC and HfB2-SiC Composites 1176–1181 (Trans Tech Publ).
Zhang, Y., Tan, D. W., Guo, W. M., Wu, L. X., Sun, S. K., You, Y., Lin, H. T. & Wang, C. Y. Improvement of densification and microstructure of HfB2 ceramics by Ta/Ti substitution for Hf. J. Am. Ceram. Soc. 103, 103–111 (2020).
Baharvandi, H. R. & Mashayekh, S. Effects of SiC content on the densification, microstructure and mechanical properties of HfB2–SiC composites. Int. J. Appl. Ceramic Technol. 17, 449–458 (2020).
Mashayekh, S. & Baharvandi, H. R. Effects of SiC or MoSi2 second phase on the oxide layers structure of HfB2-based composites. Ceram. Int. 43, 15053–15059 (2017).
Brochu, M., Gauntt, B. D., Boyer, L. & Loehman, R. E. Pressureless reactive sintering of ZrB2 ceramic. J. Eur. Ceram. Soc. 29, 1493–1499 (2009).
Wang, S. et al. Preparing B4C–SiC–TiB2 composites via reactive pressureless sintering with B4C and TiSi2 as raw materials. J. Mater. Res. Technol. 9, 8685–8696 (2020).
Zhang, B. et al. Harmonized toughening and strengthening in pressurelessly reactive-sintered Ta0.8Hf0.2C–SiC composite. J. Eur. Ceramic Soc. 38, 5610–5614 (2018).
Ghadami, S., Taheri-Nassaj, E. & Baharvandi, H. R. Novel HfB2–SiC–MoSi2 composites by reactive spark plasma sintering. J. Alloy. Compd. 809, 151705 (2019).
Zhang, X., Li, X., Han, J., Han, W. & Hong, C. Effects of Y2O3 on microstructure and mechanical properties of ZrB2–SiC ceramics. J. Alloy. Compd. 465, 506–511 (2008).
Opila, E., Levine, S. & Lorincz, J. Oxidation of ZrB2- and HfB 2-based ultra-high temperature ceramics: Effect of Ta additions. J. Mater. Sci. 39, 5969–5977 (2004).
Yi, H. C., Guigné, J. Y., Woodger, T. C. & Moore, J. J. Combustion synthesis of HfB 2-Al composites. Metall. Mater. Trans. B 29, 877–887 (1998).
Sciti, D., Bonnefont, G., Fantozzi, G. & Silvestroni, L. Spark plasma sintering of HfB2 with low additions of silicides of molybdenum and tantalum. J. Eur. Ceram. Soc. 30, 3253–3258 (2010).
Sciti, D., Silvestroni, L. & Bellosi, A. Fabrication and properties of HfB2–MoSi2 composites produced by hot pressing and spark plasma sintering. J. Mater. Res. 21, 1460–1466 (2006).
Sciti, D. & Silvestroni, L. Processing, sintering and oxidation behavior of SiC fibers reinforced ZrB2 composites. J. Eur. Ceram. Soc. 32, 1933–1940 (2012).
Han, J., Hu, P., Zhang, X. & Meng, S. Oxidation behavior of zirconium diboride–silicon carbide at 1800 °C. Scripta Mater. 57, 825–828 (2007).
Zhang, H. B. et al. Preparation, texturing and mechanical properties of ZrB2–WSi2 ceramics via reactive hot pressing and hot forging. Adv. Appl. Ceram. 113, 389–393 (2014).
Kelly, J. The Scaled-Up Synthesis of Nanostructured Ultra-High-Temperature Ceramics and Resistance Sintering of Tantalum Carbide Nanopowders and Composites (2013).
Kurokawa, K. & Yamauchi, A. Classification of Oxidation Behavior of Disilicides 227–232 (Trans Tech Publ).
ASTM C1198-20, Standard test method for dynamic Young’s modulus, shear modulus, and Poisson’s ratio for advanced ceramics by sonic resonance, ASTM International, West Conshohocken, PA (2020). https://www.astm.org.
Chicot, D. & Lesage, J. Absolute hardness of films and coatings. Thin Solid Films 254, 123–130. https://doi.org/10.1016/0040-6090(94)06239-H (1995).
Evans, A. G. & Charles, E. A. Fracture toughness determinations by indentation. J. Am. Ceram. Soc. 59, 371–372 (1976).
Khodaei, M., Yaghobizadeh, O., Ehsani, N., Baharvandi, H. R. & Dashti, A. The effect of TiO2 additive on sinterability and properties of SiC–Al2O3–Y2O3 composite system. Ceram. Int. 44, 16535–16542 (2018).
Namini, A. S. et al. Microstructural development and mechanical properties of hot pressed SiC reinforced TiB2 based composite. Int. J. Refract Metal Hard Mater. 51, 169–179 (2015).
Ni, D.-W., Liu, J.-X. & Zhang, G.-J. Microstructure refinement and mechanical properties improvement of HfB2–SiC composites with the incorporation of HfC. J. Eur. Ceram. Soc. 32, 2557–2563. https://doi.org/10.1016/j.jeurceramsoc.2012.02.017 (2012).
Sonber, J. K. et al. Investigations on synthesis of HfB2 and development of a new composite with TiSi2. Int. J. Refract Metal Hard Mater. 28, 201–210. https://doi.org/10.1016/j.ijrmhm.2009.09.005 (2010).
Hu, C., Sakka, Y., Jang, B., Tanaka, H., Nishimura, T., Guo, S. & Grasso, S. Microstructure and properties of ZrB2–SiC and HfB2–SiC composites fabricated by spark plasma sintering (SPS) using TaSi2 as sintering aid. J. Ceram. Soc. Jpn. 118, 997–1001 (2010).
Bellosi, A., Monteverde, F. & Sciti, D. Fast densification of ultra-high-temperature ceramics by spark plasma sintering. Int. J. Appl. Ceram. Technol. 3, 32–40 (2006).
Ni, D. W., Zhang, G. J., Kan, Y. M. & Wang, P. L. Hot pressed HfB2 and HfB2–20 vol% SiC ceramics based on HfB2 powder synthesized by borothermal reduction of HfO2. Int. J. Appl. Ceram. Technol. 7, 830–836 (2010).
Zou, J. et al. High-temperature bending strength, internal friction and stiffness of ZrB2–20 vol% SiC ceramics. J. Eur. Ceram. Soc. 32, 2519–2527 (2012).
Murarka, S. P. Refractory silicides for integrated circuits. J. Vacuum Sci. Technol. 17, 775–792 (1980).
Gasch, M. J., Ellerby, D. T. & Johnson, S. M. Handbook of Ceramic Composites 197–224 (Springer, New York, 2005).
Ghadami, S., Baharvandi, H. R. & Ghadami, F. Influence of the vol% SiC on properties of pressureless Al2O3/SiC nanocomposites. J. Compos. Mater. 50, 1367–1375 (2016).
Monteverde, F. Ultra-high temperature HfB2–SiC ceramics consolidated by hot-pressing and spark plasma sintering. J. Alloy. Compd. 428, 197–205 (2007).
Athanasiou, C.-E., Hongler, M.-O. & Bellouard, Y. Unraveling brittle-fracture statistics from intermittent patterns formed during femtosecond laser exposure. Phys. Rev. Appl. 8, 054013 (2017).
Athanasiou, C. E., Zhang, H., Ramirez, C., Xi, J., Baba, T., Wang, X., Zhang, W., Padture, N. P., Szlufarska, I. & Sheldon, B. W. High toughness carbon-nanotube-reinforced ceramics via ion-beam engineering of interfaces. Carbon (2020).
Liu, X., Athanasiou, C. E., Padture, N. P., Sheldon, B. W. & Gao, H. A machine learning approach to fracture mechanics problems. Acta Mater. (2020).
Sayyadi-Shahraki, A., Rafiaei, S. M., Ghadami, S. & Nekouee, K. A. Densification and mechanical properties of spark plasma sintered Si3N4/ZrO2 nano-composites. J. Alloys Compd. 776, 798–806 (2019).
Padture, N. P. & Lawn, B. R. Toughness properties of a silicon carbide with an in situ induced heterogeneous grain structure. J. Am. Ceram. Soc. 77, 2518–2522 (1994).
Ko, I.-Y., Park, J.-H., Yoon, J.-K., Doh, J.-M. & Shon, I.-J. Properties and synthesis of dense nanostructured VSi2–SiC by high-frequency induction heated combustion. Met. Mater. Int. 16, 219–223 (2010).
Asl, M. S., Nayebi, B., Ahmadi, Z., Parvizi, S. & Shokouhimehr, M. A novel ZrB2–VB2–ZrC composite fabricated by reactive spark plasma sintering. Mater. Sci. Eng. A 731, 131–139 (2018).
Kang, H.-K. & Kang, S. B. Thermal decomposition of silicon carbide in a plasma-sprayed Cu/SiC composite deposit. Mater. Sci. Eng. A 428, 336–345 (2006).
Smith, J. F. The Si−V (silicon–vanadium) system: Addendum. Bull. Alloy Phase Diagrams 6, 266–271 (1985).
Ni, D.-W., Liu, J.-X. & Zhang, G.-J. Pressureless sintering of HfB2–SiC ceramics doped with WC. J. Eur. Ceram. Soc. 32, 3627–3635 (2012).
Liu, J.-X. Zhang, G.-J., Xu, F.-F., Wu, W.-W., Liu, H.-T., Sakka, Y., Nishimura, T., Suzuki, T. S., Ni, D.-W. & Zou, J. Densification, microstructure evolution and mechanical properties of WC doped HfB2–SiC ceramics. J. Eur. Ceram. Soc. 35, 2707–2714 (2015).
Monteverde, F. & Bellosi, A. Microstructure and properties of an HfB2-SiC composite for ultra high temperature applications. Adv. Eng. Mater. 6, 331–336 (2004).
Hu, D.-L., Zheng, Q., Gu, H., Ni, D.-W. & Zhang, G.-J. Role of WC additive on reaction, solid-solution and densification in HfB2–SiC ceramics. J. Eur. Ceram. Soc. 34, 611–619 (2014).
Piriou, C. et al. Sintering and oxidation behavior of HfB2–SiC composites from 0 to 30 vol% SiC between 1450 and 1800 K. Ceram. Int. 45, 1846–1856. https://doi.org/10.1016/j.ceramint.2018.10.075 (2019).
Liu, J.-X. et al. Densification, microstructure evolution and mechanical properties of WC doped HfB2–SiC ceramics. J. Eur. Ceram. Soc. 35, 2707–2714. https://doi.org/10.1016/j.jeurceramsoc.2015.04.009 (2015).
Zou, J. et al. Chemical reactions, anisotropic grain growth and sintering mechanisms of self-reinforced ZrB2–SiC doped with WC. J. Am. Ceram. Soc. 94, 1575–1583 (2011).
Guo, S., Liu, T., Ping, D.-H. & Nishimura, T. Enhanced high-temperature strength of HfB2–SiC composite up to 1600 °C. J. Eur. Ceram. Soc. 38, 1152–1157. https://doi.org/10.1016/j.jeurceramsoc.2017.12.040 (2018).
Acknowledgements
The first author is very tankful of Mr. Mohammad Amin Davoudabadi for language editing of this article.
Author information
Authors and Affiliations
Contributions
S.Ghadami: conceptualization, methodology, investigation, writing—original draft. E.Taheri-Nassaj: supervision, writing—review and editing. H.R.Baharvandi: supervision, writing—review and editing. F.Ghadami: methodology, investigation, writing—review and editing. All authors reviewed the manuscript.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Publisher's note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Ghadami, S., Taheri-Nassaj, E., Baharvandi, H.R. et al. Effect of in situ VSi2 and SiC phases on the sintering behavior and the mechanical properties of HfB2-based composites. Sci Rep 10, 16540 (2020). https://doi.org/10.1038/s41598-020-73295-7
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41598-020-73295-7
- Springer Nature Limited
This article is cited by
-
Improvement of mechanical properties of HfB2-based composites by incorporating in situ SiC reinforcement through pressureless sintering
Scientific Reports (2021)
-
A comprehensive study on the microstructure evolution and oxidation resistance of conventional and nanocrystalline MCrAlY coatings
Scientific Reports (2021)
-
Characterization of MCrAlY/nano-Al2O3 nanocomposite powder produced by high-energy mechanical milling as feedstock for high-velocity oxygen fuel spraying deposition
International Journal of Minerals, Metallurgy and Materials (2021)