Abstract
Mo-Ni-B-Al as-cast alloys containing 35.5-58.7 wt% Mo, 23.0-57.6 wt% Ni, 3.3-5.2 wt% B, and 2.2-13.5 wt% Al were synthesized by Self-Propagating High-Temperature Synthesis (SHS) using a mixture of MoO3, NiO, B2O3 and Al powders in order to obtain low-cost Mo2 NiB2 containing hard materials. The first series of experiments were performed using 1.05 times the stoichiometric amount of Al. In the second series of experiments, FactSage thermochemical modeling software was used to minimize Al increasing the Mo2NiB2 formation in the as-cast alloys. The products were characterized by using atomic absorption spectrometry (AAS), X-ray diffraction (XRD), scanning electron microscopy (SEM) and micro-hardness techniques.
1 Introduction
Hard alloys are used in a broad range of applications due to their excellent properties such as high hardness and wear resistance as well as high toughness. The hard alloys based on wolfram carbide are the most widely used in various industrial areas [1]. However, due to the rare and uneven distribution of tungsten resources, some recent studies have focused on finding alternative hard materials with less or no tungsten in composition [2].
Transition metal borides are known for their unique physical, chemical and mechanical properties such as good refractoriness, chemical inertness, high hardness, and metallic conductivity. Among the ternary boride compounds reported in Mo-Ni-B system, Mo2NiB2 is the promising candidate for the reinforcement phase of the boride base cermets in wear resistant applications [3, 4]. Mo2NiB2 possesses orthorhombic crystal structure, with a Vickers hardness of 1500-2000HV. It wasfound that the addition of 10-15 wt% Cr into the ternary compound imparts high elastic modulus that is comparable to that of tungsten carbides [2]. Because of the above-mentioned properties and excellent corrosion resistance, the hard alloys containing Mo2NiB2 have already been applied for plastic injection molding machine parts, cutters for heat sealers, drills for sand molds, etc. [4, 5].
There are some reported studies on the Mo2NiB2 containing hard alloys in the literature. For example, Takagi et al. synthesized the hard alloys consisting of Mo2NiB2 complex boride as a reinforcement phase and metallic Ni as a binder using reaction boronizing sintering method [6, 7, 8, 9]. In their study, these hard materials were formed by insitu liquid phase reactions starting from pure elements or high purity alloy powders. They claimed that the initial Mo/B ratio has an influence on the formation of complex borides [5]. Moreover, they found that the addition of different alloying elements to these ternary hard alloys changes the boride structure that causes remarkable improvements in mechanical properties [9]. In their another study, they proved that Mo2NiB2+Ni two-phase hard alloys causes significant improvements such as high transverse rupture strength (1.7 GPa), high fracture toughness and also superior corrosion resistance in contact with molten fluorocarbon resin [10]. However, this production method has some drawbacks such as high energy consumption, expensive raw materials, and difficulties in large-scale productions. Therefore, choosing an inexpensive production method for these hard materials to increase their abundance and their usage in wider range of applications has great importance.
The self-propagating high temperature synthesis method (SHS) is a self-sustained combustion process that is used in the production of many different advanced materials. SHS methods provide various advantages such as short process time and low energy consumption that make them suitable for the production of different materials including boride based ceramics [11], intermetallic compounds [12], binary or ternary alloys [13], heat resistant refractory materials [14] etc. The thermite-type SHS processes, which have highly exothermic reduction-oxidation reactions, were used in many industrial applications [16, 17, 18]. Recently, the SHS method was used for the production of the as-cast Mo2NiB2-Ni metal matrix composites by using a centrifugal machine. Sanin et al. used metallic oxides and elemental boron as the raw materials for the aluminothermic-SHS reaction under the acceleration values (a) ranging from 1 to 100 g (g: gravity) [19]. They concluded that the yield of the alloy products increases to nearly 100% by increasing a/g. Nevertheless, the product capacity, time and energy consumptions are the limitations in the use of centrifugal machines for the SHS processes.
Therefore, the present work aimed the production of hard alloys containing complex borides by using simple and low cost SHS method under earth-gravity (1 g) and ambient conditions. The mixtures of MoO3, NiO, B2O3 and Al powders with different ratios were used as the raw materials. Also utilizing FactSage simulations [20], the thermodynamical mechanisms of simultaneous formations of the nickel-based solid solutions and boride compounds in Mo-Ni-B-Al systems were investigated.
2 Experimental Studies
In the SHS experiments, MoO3 (Alfa Aesar, 99.5% pure, particle size <60 μm),NiO (99% pure, particle size<40 μm), B2O3 (98% pure, particle size<20 μm), Al (99.7% pure, particle size <60 μm) powders were used as starting materials. B2O3 was obtained by the calcination of pure boric acid (Eti Holding Inc. 99.5% pure) in a nickel crucible at 800∘C for 2h. The powders with different ratios were prepared and then were dried in an oven at 105∘C for 30 minutes. After thoroughly mixing of powders in the turbula mixer, about 140 g of the mixture was placed into a copper crucible with a height of 140 mm and an internal diameter of 50 mm and a wall thickness of 5 mm. Due to the release of high amounts of gases during the aluminothermic process, the experiments were performed in open crucibles under air. A tungsten filament on top of the powder mixture which is connected to a power supply initiated the exothermic reaction. After the SHS process, the alloy part was separated from slag and then was metallographically prepared for further analysis. The compositions of the initial reaction mixtures used in the experiments were presented in Table 1. The first series of experiments were performed using 1.05 times the stoichiometric amount of Al to achieve full reduction of the different initial oxide mixture. In the second series experiments, the compositions in the initial mixtures were determined by FactSage thermo-chemical modeling software [20] to minimize Al content, increasing the Mo2NiB2 formation in the as-cast alloys.
The amounts of the initial raw materials amount used in the experiments
| Series of Exp | Exp No | MoO3 | NiO | B2O3 | Al | Times the stoich. Al amount |
|---|---|---|---|---|---|---|
| Weight,g | ||||||
| 1 | Sample A | 58.7 | 22.8 | 18.5 | 41.8 | 1.05 |
| Sample B | 57.3 | 28.9 | 13.8 | 39.1 | 1.05 | |
| Sample C | 54.6 | 32.2 | 13.2 | 38.4 | 1.05 | |
| 2 | Sample D | 46.9 | 28.1 | 25.0 | 35.0 | 0.80 |
| Sample E | 41.0 | 34.4 | 24.6 | 34.2 | 0.80 | |
| Sample F | 28.6 | 42.9 | 28.6 | 30.3 | 0.70 | |
The crystal structure and the phases of the final products were determined by X-ray diffraction measurements (XRD, PANalytical PW3040/60 with a Cu-Kα radiation). The microstructure, morphology and the composition of phases were characterized by scanning electron microscopy equipped with an energy dispersive spectroscopy (SEM/EDS, Jeol JSM-840) and Image® image analysis software. The elements were analyzed by atomic absorption spectrometer (AAS, Perkin-Elmer 1100B). TheVickers hardness test (Shimadzu Corporation HMV) with 5N indentation load was also carried out on the specimens.
3 Results and Discussion
The stoichiometrically calculated compositions and the chemical analysis results of the as-cast alloys from the first series of experiments obtained by AAS are shown in Table 2. The obtained results revealed that the actual alloy compositions are different from the calculated ones due to the high amount of Al in the alloys and above-mentioned SHS nature. The aluminum content in the samples varied from 8.36 to 13.05 wt%,whereas boron content changed between 3.93 and 5.22 wt%. The Mo/Ni weight percent ratios in the obtained samples were detected to be between 2.55 and 1.65.
The stoichiometrically calculated and actual elemental compositions of the as-cast alloys from the first series of experiments
| Exp No | wt% | ||||||
|---|---|---|---|---|---|---|---|
| Stoich. Calculated Compositions | Actual Compositions | ||||||
| Mo | Ni | B | Mo | Ni | B | Al | |
| A | 62.1 | 28.8 | 9.11 | 58.7 | 23.01 | 5.22 | 12.48 |
| B | 58.5 | 34.9 | 6.6 | 55 | 25.55 | 4.06 | 13.5 |
| C | 54.9 | 38.9 | 6.2 | 52.9 | 32.04 | 3.93 | 8.36 |
The backscattered electron (SEM/BSE) images of the as-cast alloys obtained by 1.05 times the stoichiometric amount of Al are shown in Figure 1(a-c). The elemental distributions of the phases in as-cast alloys revealed by Energy Dispersive Spectroscopy (EDS) scans are listed in Table 3. The results show that all samples are intermetallic matrix composites (IMCs). The common matrix in the samples was detected as beta (NiAl) nickel aluminide intermetallic phase which is a consequence of high Al content in the initial reactant mixture. Among the alloys studied in this work, sample A has the highest Mo content (58.7 wt%). Figure 1a and EDS scans prove that the molybdenum diboride (MoB2) and molybdenum mono boride (MoB) are the two reinforcement phases in sample A. As seen in Figure 1b and Figure 1 also confirms that the Mo2NiB2 content increases with decreasing Al concentration in the alloy. The area fractions of distributed particles and overall matrix were measured by image analysis method from the SEM images using ×500 magnification. The reinforcement/matrix ratio for alloys A, B and C were found to be 0.92, 0.69 and 1.04, respectively, in rather good agreement with the measured alloy composition. In fact alloy B, which has low Mo content and high residual aluminum, show the lowest reinforcement/matrix ratio.
SEM/BSE images of the as-cast alloys from the first series of experiments (×500) a) Sample A, b) Sample B, and c) Sample C.
The EDS measured elemental compositions for crystalline phases shown in Figures 1(a), (b), and (c)
| wt% | ||||||
|---|---|---|---|---|---|---|
| No | Mo | Ni | B | Al | Phase | |
| Figure 1(a) | 1 | 1.30 | 67.91 | - | 30.79 | β-NiAl |
| 2 | 88.57 | 1.38 | 10.05 | - | MoB | |
| 3 | 83.31 | - | 16.69 | - | MoB2 | |
| 4 | 78.55 | 1.61 | 19.84 | - | MoB2 | |
| 5 | 79.04 | 1.73 | 19.23 | - | MoB2 | |
| Figure 1(b) | 1 | - | 68.95 | - | 31.05 | β-NiAl |
| 2 | 53.95 | 20.45 | 19.39 | 6.21 | Mo2NiB2 | |
| 3 | 2.53 | 68.41 | - | 29.06 | β-NiAl | |
| 4 | 84.72 | 2.41 | 12.87 | - | MoB2 | |
| 5 | 81.64 | 3.67 | 14.69 | - | MoB2 | |
| Figure 1(c) | 1 | 4.29 | 74.34 | - | 21.37 | β-NiAl |
| 2 | 70.10 | 16.14 | 13.76 | - | Mo2NiB2 | |
| 3 | 84.98 | 3.55 | 11.47 | - | MoB | |
Before the second series of the experiments, some additional thermochemical calculations were employed to describe the phase transformations occurring during the SHS process and the solidification. The modeling was performed by using the advanced “Equilib” module of FactSage 7.1 software. During the calculations, SGTE 2014 database was selected to detect metallic liquid and solid solutions in the product. FACT Solutions database was chosen for the molten slag phase. A stoichiometric compound Mo2NiB2 was added to the calculations from a private database, whereas all gas and other stoichiometric solid phases were selected from the FACT Pure Substances database. It is obvious that as the ratio of the initial components changes, the product composition will be different. However, the following calculation trials were done for a better understanding of the reaction mechanisms which predict the important steps involved in the whole process.
In the first trial, 40 g of MoO3, 40 g of NiO and 20 g of B2O3 were equilibrated with 0-40 g of Al. The reaction of the process was assumed as adiabatic (ΔH=0) and the initial reaction temperature was selected as 25∘C. In order to avoid the complexity of the drawing, only the calculated phases in the liquid alloy, total gas and slag products, and adiabatic temperature (Tad) values are shown versus Al addition in Figure 2. The chemical species formed during the process and their amounts change largely through the reduction of oxides with different amount of Al. Tad of the process increases with increasing Al addition due to the exothermic nature of the SHS reactions. At low Al additions and Tad values, B2O3 first reacts with Al2O3 and forms a slag phase. As seen in the figure, having more than a certain level of boron (>~3 wt%) in the alloy requires a high amount of Al, which results in a higher Tad value (> 2400∘C) with a dissolution of Al in the as-cast alloy. Since NiO reduction to metallic nickel generates a high amount of heat, dominant species in the initial gaseous phase (between 8-20 g Al) are mainly composed of Mo2O6, Mo3O9 and Mo4O12 due to the evaporation of some MoO3. After a certain amount of Al (>20 g Al), the simultaneous reductions of NiO and MoO3 stimulate the release of gaseous boron oxide products such as (BO)2, B2O3, and AlBO2. The equilibrium conditions were assumed in a closed system at 1 atm in the simulation. So, it is possible to reduce almost all gaseous molybdenum species and some boron oxide particles in the closed system to the alloy phase. In the experiments, however, the cover of the copper reactor vessel was not sealed enough to prevent gas leakage (i.e. the molybdenum and boron oxide species) which resulted in a certain decrease in the alloy recovery.
Selected phases and Tad values of an SHS process versus Al by FactSage Calculation (40 g MoO3+40 g NiO + 20 g B2O3+ <5-40> g Al)
It was also revealed that even when the stoichiometric amount of Al (~40 g) was used to attempt to reduce all oxides in the mixture, a considerable amount of Al (5.4 wt% Al) dissolved in the alloy product with a high Tad value (~2620∘C).
The second trial of the calculation was done for predicting the solidification of an SHS produced alloy melt to estimate the possible microstructures. For this aim, the alloy composition consisting of 50 wt% Ni, 44 wt% Mo, 4 wt% B, and 2 wt% Al by mass was selected for the equilibrium solidification model starting from 1600∘C down to 100∘C. Figure 3 shows that Mo2NiB2 is the first solid product in the liquid alloy. The solid solution -Ni and Mo2NiB2 phases coexist below solidus temperature (1360∘C). The calculation suggests that the nucleation ofMo2B and Ni3Al phases begin at 680∘C and 601∘C, respectively. The nickel and molybdenum to form Ni3Al and Mo2B phases are supplied from α-Ni and Mo2NiB2 phases. The subsequent calculations revealed the possibility of MoB and Ni3B phases depending on Mo/Ni ratio in the alloy. It is noted that Al concentration in the alloy is also an important parameter for the phase formations. For example, the excess aluminum in the initial SHS mixture may lead to some other possible intermetallics in the alloy such as Ni5Al3, NiAl, and Ni2Al3.
FactSage calculation of a selected SHS alloy for equilibrium solidification (50% Ni, 44% Mo, 4% B, and 2 wt% Al, by mass)
On the basis of above FactSage results, in order to decrease the aluminum concentration in the alloy, the aluminum in the initial mixture has to be less than stoichiometric amount required for the full reduction from the oxides. Thus, in the second series of experiments, a relatively higher amount of B2O3 was used to depress the Tad value releasing higher amounts of boron containing gases. The compositions of the initial mixtures determined by using FactSage program to obtain the as-cast alloys with high Mo2NiB2 and with low Al concentrations are shown in Table 1. The FactSage calculated compositions and Tad values and chemical analysis results of the product samples from the second series of experiments obtained by AAS are shown in Table 4. The actual alloy compositions were found similar to the calculated ones. Tad values were relatively low and varied between 2233 and 2512∘C. The Mo/Ni weight percent ratios in the samples were found to be between 1.18 and 0.62. The aluminum contents in the samples varied from 2.2 to 3.02 wt%, whereas boron contents changed between 3.3 and 4.1 wt%.
FactSage calculated compositions and Tad values, and actual elemental compositions of the as-cast alloys from the second series of experiments.
| No | wt% | ||||||||
|---|---|---|---|---|---|---|---|---|---|
| FactSage Calculated Compositions | Actual Compositions | ||||||||
| Mo | Ni | B | Al | Mo | Ni | B | Al | Tad(°C) | |
| D | 55.15 | 38.22 | 5.57 | 1.05 | 50.2 | 42.6 | 3.28 | 3.02 | 2512 |
| E | 47.24 | 46.04 | 5.42 | 1.30 | 43.08 | 49.27 | 3.3 | 2.3 | 2381 |
| F | 34.0 | 59.71 | 5.51 | 0.78 | 35.51 | 57.59 | 4.1 | 2.2 | 2233 |
The XRD analyses of the as-cast products obtained from the second series of experiments by using the initial mixture of MoO3: NiO: B2O3: Al are presented in Figure 4. Unlike the previously produced as-cast alloys, the matrix is mainly composed of τ-nickel aluminum boride (τ-Ni20.5Al2.5B6) and Y′-nickel aluminide (Y′-Ni3Al) phases. τ-borides with a M23C6-type cubic structure in ternary Ni-Al-B system have a rather broad range of homogeneity and are formed due to partial replacement of Al atoms by boron [21]. In Figure 4a, the order of the peak intensity of the phases from highest to lowest was found to be τ-Ni20.5Al2.5B6, Y′-Ni3Al, α and β-MoB, MoB2, β-NiAl, and Mo2NiB2. Figure 4(b) shows that when the Mo/Ni weight percent ratio decreased from 1.18 to 0.87,Mo2NiB2 appears to be the main phase in the as-cast alloy. The second reinforcement phase detected in the alloy wasα-MoB.With the further increase in Ni content from 49.27 to 57.59 wt%,MoB phase disappears and τ-Ni20.5Al2.5B6 becomes the dominant phase in the as-cast alloy having a highMo2NiB2 content (Figure 4c).
XRD analysis of products with compositions of a) Sample D, b) Sample E, c) Sample F (∘Mo2NiB2, ◊ τ-Ni20.5Al2.5B6, Y′- Ni3Al, ∎ β-NiAl, ▴ Orthorhombic α-MoB, ▵ Tetragonal β-MoB, □ Hexagonal MoB2)
Selected SEM/BSE images of the three as-cast alloys from the second series of experiments are shown in Figure 5a shows the elongated particles (light gray) which are distributed throughout the matrix region (dark gray). The higher magnification SEM image in Figure 5b and the corresponding EDS analysis presented in Table 5a reveals the following phases: a) MoB (1, Whitish gray) formed in the middle of the grains b) elongated Mo2NiB2 particles near the boundaries (2, light gray), and the matrix c) consisting of Ni20Al3B6 (3, dark gray) with mixture of Ni3Al and NiAl (4, black dot) phases.
SEM/BSE images of the as-cast alloy sample D with the magnifications of a) ×500 and, b) ×2000
The EDS measured elemental compositions for crystalline phases shown in Figures 5(b), 6(b) and 7(b).
| wt% | ||||||
|---|---|---|---|---|---|---|
| No | Mo | Ni | B | Al | Phase | |
| Figure 5(b) | 1 | 89.48 | 2.06 | 8.47 | MoB | |
| 2 | 75.46 | 17.96 | 6.58 | Mo2NiB2 | ||
| 3 | 84.34 | 7.18 | 8.47 | τ-Ni20.5Al2.5B6 | ||
| 4 | 85.74 | 14.26 | Y′-Ni3Al | |||
| 5 | 74.06 | 25.94 | NiAl | |||
| Figure 6(b) | 1 | 85.29 | 14.71 | MoB2 | ||
| 2 | 70.59 | 22.41 | 7.00 | Mo2NiB2 | ||
| 3 | 90.97 | 5.27 | 3.77 | τ-Ni20.5Al2.5B6 | ||
| 4 | 87.1 | 12.9 | Y′-Ni3Al | |||
| Figure 7(b) | 1 | 75.95 | 18.92 | 5.13 | Mo2NiB2 | |
| 2 | 71.11 | 24.65 | 4.24 | Mo2NiB2 | ||
| 3 | 87.1 | 12.9 | Y′-Ni3Al | |||
| 4 | 92.42 | 3.83 | 3.75 | τ-Ni20.5Al2.5B6 | ||
Figure 6a shows the plate-like particles (light gray) which are almost uniformly distributed throughout the region. The higher magnification SEM image shown in Figure 6b reveals the existence of a) plate-like Mo2NiB2 (1, light gray) particles , b) α-MoB (2, whitish gray) formed in the coarse Mo2NiB2 grains, and c) τ-Ni20.5Al2.5B6 (3, gray) and Ni3Al (4, dark gray) phases as the matrix.
SEM/BSE images of the as-cast alloy sample E with the magnifications of a) ×500 and, b) ×2000
Figure 7a shows that the plate-like particles (gray) are much longer and randomly distributed throughout the region. The higher magnification SEM image shown in Figure 7b reveals the existence of a) plate-like Mo2NiB2 phases (1 and 2) with different Mo/Ni ratios, and b) Ni3Al (3, dark gray) and τ-Ni20.5Al2.5B6 (4, gray) phases as the matrix. The reinforcement/matrix ratios obtained from the SEM images of alloys D, E and F, were calculated to be 1.22, 1.27 and 0.72 respectively. It becomes more evident in alloy F that, as Ni forms the main matrix phases such as NiAl, Ni3Al and Ni20.5Al2.5B6, the reinforcement content decreased with a certain amount of Ni in the final product.
SEM/BSE images of the as-cast alloy sample F with the magnifications of a) ×500 and, b) ×2000
Vickers hardness measurements were performed on the Mo-Ni-B-Al hard alloys with 10 tests each and the average values are presented in Figure 8. As expected, due to the different binary or ternary matrix and reinforcements phases, as well as different reinforcement/matrix ratios, the alloys showed large deviations in the hardness values ranging from 843±71.64 HV to 1196±71.19 HV. For example, the alloys A and B showed relatively lower hardness values, since high amount of Al resulted in NiAl formation in the matrix.
Variation of hardness values in products with different compositions
The hardness value of alloy C (943 HV±28.78) slightly increased due to the relatively lower Al concentration in the matrix and higher ternary boride formation in the reinforcement phase. Sample D which has the highest hardness value (1196 HV±71.19), contains four reinforcement phases (α and β-MoB, MoB2 and Mo2NiB2) and three matrix phases (τ-Ni20.5Al2.5B6, NiAl, and ′-Ni3Al). As expected in alloy F, after a certain value of Ni, the hardness value decreased due to increasing matrix/reinforcement ratio in the as-cast alloys. It can be concluded that the reinforcing boride phases improved the hardness values of the composites with NixAl (x=1,3) phase matrix, as also reported in the literature [22].
4 Conclusion
On the basis of the presented modeling and experimental results of the SHS process of MoO3, NiO and B2O3 with Al to produce Mo2NiB2 containing hard materials, the following conclusions can be made: the B2O3 amount was used higher than its stoichiometric ratio which resulted in lower adiabatic temperature and lower Al residues in the products. Also, as the Mo/Ni weight ratio and Al content decreased, the formation feasibility of Mo2NiB2 ternary boride increased. Therefore, the following phases were detected in the as-cast alloys respectively: tetragonal MoB and Mo2NiB2 as reinforcement phases and Y′-Ni3Al and τ-Ni20.5Al2.5B6 as matrix phases. The average hardness values in the as-cast alloys varied between 843±71.64 HV and 1196±71.19 HV due to the compositional variations and differences in the reinforcement/matrix ratio. Further study (i.e. different compositions, fracture toughness, wear resistance tests, etc) is needed to properly assess the full potential of SHS produced Mo-Ni-B-Al as-cast alloys for special applications.
Acknowledgement
The authors are gratefully acknowledged for the financial support of The Scientific and Technological Research of Turkey (TUBITAK, Project No: 213M555), Istanbul Technical University Research Foundation (ITU-BAP, Project No: 39662) and Russian Foundation for Basic Research (RFBR, Project No:14-08-91374).
References
[1] V.K. Sarin, D.Mari, and L. Lianes, Comprehensive Hard Materials,Elsevier, Amsterdam, (2014).Search in Google Scholar
[2] K. Takagi,W. Koike, A. Momozawa, and T. Fujima, Solid State Sci., 14 (2012) 1643-1647.10.1016/j.solidstatesciences.2012.05.009Search in Google Scholar
[3] W. Yongguo and L. Zhaoqian, Mater. Res. Bull., 37 (2002) 417423.Search in Google Scholar
[4] K. Takagi, J. Solid State Chem., 179 (2006) 2809-2818.10.1016/j.jssc.2006.01.023Search in Google Scholar
[5] K. Takagi and Y. Yamasaki, J. Solid State Chem., 154 (2000) 263-268.10.1006/jssc.2000.8847Search in Google Scholar
[6] K. Takagi, Y. Yamasaki, and K. Hirata, Mater. Sci. Forum, 539 (2007) 803-809.10.4028/www.scientific.net/MSF.539-543.803Search in Google Scholar
[7] Y. Yamasaki, M. Nishi, and K. Takagi, J. Solid State Chem., 177 (2004) 551-555.10.1016/j.jssc.2003.03.008Search in Google Scholar
[8] K. Takagi, Mater. Chem. Phys., 67 (2001) 214-219.10.1016/S0254-0584(00)00442-9Search in Google Scholar
[9] Y. Shiota, Y. Miyajima, T. Fujima, and K. Takagi, J. Phys.: Conf. Ser. 176 (2009) 012046.10.1088/1742-6596/176/1/012046Search in Google Scholar
[10] K. Hirata, K. Iwanaga, Y. Yamasaki, and K. Takagi, Mater. Sci. Forum, 534 (2007) 1157-1160.10.4028/www.scientific.net/MSF.534-536.1157Search in Google Scholar
[11] S. Yazici and B. Derin, Int. J. Refract. Metals HardMater., 29 (2011) 90-95.10.1016/j.ijrmhm.2010.08.005Search in Google Scholar
[12] T. Chanadee, J. Wannasin, and S. Niyomwas, J. Ceram. Soc. Jpn., 122 (2014) 496-501.10.2109/jcersj2.122.496Search in Google Scholar
[13] B. Derin, U. Demircan, and O. Yucel, Met. Mater. Int., 15 (2009) 331-336.10.1007/s12540-009-0331-1Search in Google Scholar
[14] L. Guanghua, L. Jiangtao, and C. Kexin, Int. J. Refract. Metals Hard Mater., 39 (2013) 90-10210.1016/j.ijrmhm.2012.09.002Search in Google Scholar
[15] A. Varma, A. S. Rogachev, A. S. Mukasyan, and S. Hwang, Advances in Chemical Engineering, Elsevier, Amsterdam, 24 (1998) pp. 79-226.Search in Google Scholar
[16] E. A. Levashov, A. S. Mukasyan, A. S. Rogachev, and D. V. Shtan-sky, Int. Mater. Rev., 62 (2017) 203-239.10.1080/09506608.2016.1243291Search in Google Scholar
[17] V.I. Yukhvid, Pure Appl. Chem, 64 (1992) 977-988.10.1351/pac199264070977Search in Google Scholar
[18] G.F. Tavadze and A.S. Shteinberg, Production of Advanced Materials by Methods of Self-Propagating High-Temperature Synthesis, Springer, Heidelberg, (2013).10.1007/978-3-642-35205-8Search in Google Scholar
[19] V. Sanin, D. Ikornikov, D. Andreev, V. Yukhvid, B. Derin, and O. Yucel, Int. J. Self Propag. High Temp. Synth., 24 (2015) 161-170.10.3103/S1061386215030097Search in Google Scholar
[20] C.W. Bale, E. Bélisle , P. Chartrand, S.A. Decterov, G. Eriksson, A.E. Gheribi, et al., CALPHAD, 54 (2016) 35-53.10.1016/j.calphad.2016.05.002Search in Google Scholar
[21] V. N. Sanin, D. M. Ikornikov, D. E. Andreev, V. I. Yukhvid, E. A. Levashov, and Yu.S. Pogozhev, Int. J. Self Propag. High Temp. Synth., 23 (2014) 232-239.10.3103/S1061386214040098Search in Google Scholar
[22] P. Hyjek, I. Sulima, and L. Jaworska, Arch. Metall. Mater., 62 (2017) 1511-1520.10.1515/amm-2017-0234Search in Google Scholar
© 2019 S. R. Moghaddam et al., published by De Gruyter
This work is licensed under the Creative Commons Attribution 4.0 Public License.
