International Scholarly Research Notices

International Scholarly Research Notices / 2012 / Article

Research Article | Open Access

Volume 2012 |Article ID 670389 |

G. P. Khanra, Abhay K. Jha, S. GiriKumar, D. K. Mishra, T. T. Sarvanan, S. C. Sharma, "Development of MoSi2-SiC Component for Satellite Launch Vehicle", International Scholarly Research Notices, vol. 2012, Article ID 670389, 6 pages, 2012.

Development of MoSi2-SiC Component for Satellite Launch Vehicle

Academic Editor: D. Escalera
Received07 Aug 2012
Accepted29 Aug 2012
Published14 Oct 2012


Intermetallic base MoSi2-SiC composite, an excellent high temperature oxidation-resistant material meant for the aerospace structural applications between 1600°C and 1700°C under oxidizing environment, has been developed successfully using powder metallurgy techniques. Mechanically milled (MM) MoSi2 powder, blended with SiC particulate was consolidated by vacuum hot pressing, yielded about 98.5% theoretical density. The composite has been characterized for physical, mechanical, and thermal properties. Properties were found satisfactory. Machining of semis to intricate shape was possible through electro-discharge machining (EDM) process. Plasma arc jet test (PAJT) under argon and argon + oxygen environment has proved its excellent high temperature oxidation resistance properties as it could sustain high heat flux up to 250 W/cm2 under oxidizing environment. The component realized has full potential to be used in critical aerospace application. This paper highlights the details of experimental work carried out and its characteristic properties attained.

1. Introduction

Molybdenum disilicide (MoSi2) is an intermetallic with tetragonal unit cell arrangement (Figure 1) and has strong potential for high temperature structural applications in aerospace industries due to its high melting point (2030°C) and ability to undergo plastic deformation above 1200°C. Molybdenum disilicide possesses outstanding oxidation resistance up to 1700°C due to the formation of an impervious film of SiO2 on the surface which prevents further oxidation. Being electrically conductive, it could be machined by electro-discharge machine (EDM) to desired shapes [13]. Apart from wide use as heating element, it is also used in power generation components, heat exchanger, filters, turbine blades, vanes, combustion nozzles, turbocharger rotors, valves, and so forth [4]. However, its room temperature fracture toughness is poor compared to other high temperature metallic systems. Other mechanical properties such as yield strength and creep strength gradually decrease above 1100°C. Hence, reinforcement of the matrix with thermally stable ceramic particles or whiskers which can significantly improve the fracture toughness at room temperature as well as high temperature properties is recommended [57]. It is chemically compatible with a number of ceramic constituents such as SiC, Si3N4, TiC, TiSi2, ZrO2, Al2O3, and so forth, which could be judicially selected as reinforcement for particular use and temperature regime [8, 9].

In the present work, MoSi2-20v% SiC composite discs were consolidated using vacuum hot press (VHP) to near theoretical density (TD) using mechanically milled (MM) MoSi2 powder and SiC particulates. The composite was characterised for mechanical properties and was evaluated for its thermal property. Uniform distribution of SiC particulates in MoSi2 matrix was confirmed by optical microscopy. Heat flux test on the composite carried out under oxidizing plasma indicated its excellent oxidation resistance and its ability to withstand high heat flux. Based on the technical properties achieved, a critical component of Indian space programme was fabricated out of this.

2. Processing

Mo and Si powders were blended in stoichiometric ratio as starting ingredients for mechanical milling (MM). The mixture along with grinding media (SS440C balls) in 1 : 10 ratio was charged in Union Process 01HD attritor mill (Figure 2). The milling time was optimized based on particle size measurement in periodic interval. Mo powder (99.8% purity) with 7 μm (avg.) particle size was reduced at 800°C in H2 prior to MM. Reduced Mo powder was sieved and blended with below-38-microns Si powder (99.6% purity). Milling was performed under protective (Argon) atmosphere at 400 rpm for an optimized time of 20 hrs (Figure 3). The particle size distribution of MoSi2 using bimodal pattern and average size of particles observed under scanning electron microscope are shown in Figure 4.

SiC powder of 21-micron particle size (avg.) was treated with 40% HF solution to remove SiO2 prior to blending with mechanically milled (MM) MoSi2. Further processing involved vacuum degassing at 800°C for 2 hours and vacuum hot pressing (VHP) between 1500 and 1600°C for 1 hour using a pressure of 22 MPa. The heating rate was kept below 10°C/min to maintain temperature uniformity, effective degassing, and full conversion to silicides.

The hot pressing was carried out in the range 1500/1600°C with an intermediate soaking at 1200°C for 2 hrs, keeping in view of thermodynamics of the system and ensuring the following reactions, namely [10]: (i) reaction between Mo and Si to form MoSi2, (ii) transformation of lower silicides into MoSi2, and (iii) to completing and achieving near theoretical density (TD).

The probable reactions, which take place are [10, 11] as follows.Conversion of lower silicide (before melting of Si): Direct reaction (after melting of Si):

It was found that the temperature for VHP processing (1500–1600°C) to achieve near TD is much lower compared to conventional compaction and sintering (>1800°C) route. The high energy state of MM powder and formation of liquid phase due to melting of Si caused lower sintering temperature and shorter time to achieve near theoretical density in the VHP process. The similar observation has been noticed by Schwarz et al. [12] for hot pressing of MoSi2 powder made in high energy Spax mill.

3. Characterisation

Density measurement of composite was carried out by Archimedes’ principle. Optical metallography was conducted with and without etching to assess grain size of MoSi2 and dispersion of SiC particulate in the matrix. Phases have been identified through XRD analysis. Powder as well as polished specimen from hot pressed compact were analysed by using Cukα radiation. Hardness was measured on the metallographically polished specimens using Vicker’s microhardness tester on individual particles, with diamond indenter at a load of 300 g. Vicker’s macro-hardness was also measured on the composite to estimate its bulk hardness.

Mechanical properties were carried out at room temperature. Flexural strength specimens with a span (L) of 40 mm, a thickness (B) of 6 mm and width (W) of 8 mm were prepared by utilizing diamond cutter followed by utilizing smooth finish. Flexural test, a 3-point bend test, was carried out using a loading rate 0.5 mm/min in INSTRON machine as per ASTM C-1211. The flexural strength (σ) was evaluated by the expression, σ = 3 , where P was the maximum load in load-displacement curve. Compression test was conducted as per ASTM C-773 on 4 mm dia × 8 mm long test specimens using Instron machine at a loading rate of 0.5 mm/min. Modulus of elasticity was measured by ultrasonic nondestructive evaluation procedure. Longitudinal and shear waves have been used for determination of E value. Another approach, that is, estimation of E value from formula where is longitudinal wave velocity, = density, and γ = poison’s ratio, has also been used. Coefficient of thermal expansion was measured on 5 × 5 × 5 mm test specimens up to 450°C. Evaluation of machinability of the composite was carried out by drilling a 2 mm dia. through hole by EDM. The specimen was evaluated for high temperature oxidation resistance. Heat flux studies were performed on 15 mm dia × 5 mm thick specimens at 250 W/cm2 flux under argon and oxidizing atmosphere for 15 sec in plasma arc jet test facility.

4. Result and Discussion

Density measurement shows that the VHP processed composites had 99.6% and 98.6% TD when processed at 1600°C and 1500°C, respectively. Such a high densification by hot pressing for 1 hr, under 22 MPa pressure, indicates that MM processed powder had faster rate of densification. It can be inferred here that finer particle sizes (3.3 μm, Fisser’s subsieve size) of mechanically milled MoSi2-SiC is densified more readily during hot pressing due to more homogenous mixing, a higher driving force available from high particle surface area and shorter diffusion distances for both Nabaro Herring and Coble creep deformation to occur [14, 15]. It was observed that even after mechanical milling for 40 hrs, MoSi2 or other silicides of molybdenum could not form. On the other hand, particle refinement and intimate mixture of Mo and Si could take place with the progress of milling. Particle size analysis data (Figure 4) and presence of Mo and Si peaks in XRD after 40 hrs of milling (Figure 5) supported the above statement.

XRD analysis of MoSi2-SiC composite specimen, vacuum hot pressed at 1500°C and 1600°C after vacuum hot pressing at 1500–1600°C (Figure 6), confirmed presence of MoSi2 and SiC only.

The light optical photomicrographs of hot pressed MoSi2-SiC under unetched (Figure 7) and etched conditions (Figure 8) revealed presence of two phases, namely, MoSi2 and SiC. The uniform distribution of SiC particles in MoSi2 matrix was confirmed. The grain size in the composite has been found to be between 15 and 20 microns.

The room temperature physical, mechanical, and thermal properties of MoSi2-SiC composite were evaluated. The flexural strength, compressive strength, modulus of elasticity, hardness, and coefficient of expansion data are given in Table 1. The fracture in flexural test has been found to have taken place in a mixture of intergranular and transgranular mode. Elastic modulus was found to be 410 GPa which is in between individual elastic modulus of MoSi2 and SiC and in general obeys rule of mixture (ROM). It was inferred that blending of ingredients and processing temperature have significant influence on final properties achieved in the composite. Microhardness measured on individual phases and found to be about 11 GPa on MoSi2 and about 12.7 GPa on SiC particles. Bulk hardness on the composite was found to be about 11.5 GPa which was in agreement with values approximated by ROM from individual hardness of MoSi2 and SiC. Flexural and compressive strengths are found to be on higher side than predictable by ROM. This was attributed to better particle-particle bonding and uniform distribution of SiC particle in MoSi2 matrix. Machinability study gave confidence that critical shapes including through holes could be made by EDM. Study evaluating high temperature resistance of this composite at 1400°C indicated initial weight gain of 1.12 mg/cm2 for 10 hrs exposure. However, beyond 10 hrs of exposure at 1400°C, it was almost stable (Figure 9). Few moSi2-SiC composite components machined through EDM are shown in Figure 10. Plasma arc jet test under argon and argon + oxygen environment carried out (Figure 11) indicated that composite had excellent oxidation resistant property and was able to withstand high heat flux (250 W/cm2) under the above environmental conditions. The cross-section of the component subjected to high temperature oxidation was polished and observation under optical microscope confirmed retention of contour. Microstructure was stable with little grain coarsening (Figure 12).

PropertiesMoSi2-20v% SiC
MoSi2 (literature)SiC

Relative density (%TD)98.8100100
Vicker’s hardness (GPa)11.511*12.7*
Mod of elasticity (GPa)410395462
Flexural strength (MPa)338257468
Compressive strength (MPa)271026003500
Co-eff of th. exp. (/°C)

*Measured on individual particles.

5. Conclusion

(1) MoSi2-SiC composite has been consolidated by vacuum hot pressing of MM blend of Mo, Si, and SiC particulates between 1500 and 1600°C. A temperature of 1500°C and pressure of 22 MPa are found to be adequate to achieve composite having near theoretical density of 98.5%.

(2) Mechanical properties at RT are found to be greater compared to estimated values due to better bonding and uniform distribution of reinforced particles.

(3) Machining to desired shapes could be achieved through EDM process.

(4) The composite has excellent high temperature oxidation resistance properties. It successfully withstood high heat flux (250 W/cm2) under oxidizing atmosphere, thus proving potential for use in high temperature oxidizing atmosphere.


The authors wish to express their sincere gratitude to Shri P. S. Veeraraghavan, Director, VSSC, for giving permission to publish this paper.


  1. Y. L. Jeng and E. J. Lavernia, “Processing of molybdenum disilicide,” Journal of Materials Science, vol. 29, pp. 2557–2571, 1994. View at: Publisher Site | Google Scholar
  2. R. Mitra, N. E. Prasad, and Y. R. Mahajan, “REACTION hot pressed silicides and silicide matrix composites: processing, microstructure and properties,” Transaction of the Indian Ceramic Society, vol. 56, no. 3, pp. 71–78, 1997. View at: Google Scholar
  3. A. K. Vasudevan and J. J. Petrovic, “A comparative overview of molybdenum disilicide composites,” Materials Science and Engineering: A, vol. 155, pp. 1–17, 1992. View at: Publisher Site | Google Scholar
  4. J. J. Petrovic, “Mechanical behavior of MoSi2 and MoSi2 composites,” Materials Science and Engineering: A, vol. 192-193, pp. 31–37, 1995. View at: Publisher Site | Google Scholar
  5. J. J. Petrovic and R. E. Honnell, “Partially stabilized ZrO2 particle-MoSi2 matrix composites,” Journal of Materials Science, vol. 25, no. 10, pp. 4453–4456, 1990. View at: Publisher Site | Google Scholar
  6. K. Sadananda, C. R. Feng, H. Jones, and J. Petrovic, “Creep of molybdenum disilicide composite,” Materials Science and Engineering: A, vol. 155, pp. 227–239, 1992. View at: Publisher Site | Google Scholar
  7. F. D. GAC and J. J. Petrovic, “Feasibility of a composite of SiC Whiskers in an MoSi2 matrix,” Journal of the American Ceramic Society, vol. 68, no. 8, pp. C-200–CC201, 1985. View at: Publisher Site | Google Scholar
  8. Peter J. Meschter and Daniel S. Schwartz, “Silicide-matrix materials for high-temperature applications,” Journal of metals, vol. 41, no. 11, pp. 52–55, 1989. View at: Google Scholar
  9. M. J. Maloney and R. J. Hecht, “Development of continuous-fiber-reinforced MoSi2-base composites,” Materials Science and Engineering: A, vol. 155, pp. 19–31, 1992. View at: Publisher Site | Google Scholar
  10. S. C. Deevi, “Diffusional reactions in the combustion synthesis of MoSi2,” Materials Science and Engineering: A, vol. 149, pp. 241–251, 1992. View at: Publisher Site | Google Scholar
  11. R. Mitra, Y. R. Mahajan, N. E. Prasad, and W. A. Chiun, “Processing-microstructure-property relationships in reaction hot-pressed MoSi2 and MoSi2/SiCp composites,” Materials Science and Engineering: A, vol. 225, pp. 105–117, 1997. View at: Publisher Site | Google Scholar
  12. R. B. Schwarz, S. R. Srinivasan, J. J. Petrovic, and C. J. Maggiore, “Synthesis of molybdenum disilicide by mechanical alloying,” Materials Science and Engineering A, vol. 155, no. 1-2, pp. 75–83, 1992. View at: Google Scholar
  13. NIST Structural Ceramics data base no. 30.
  14. R. M. German, Powder Metallurgy Science, MPIF, 2nd edn edition, 1984.
  15. W. D. Kingery, H. K. Bowen, and D. R. Uhlmann, Introduction To Ceramics, Wiley, New York, NY, USA, 2nd edition, 1976.

Copyright © 2012 G. P. Khanra et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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