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Microstructural and tribological characterization of molybdenum–molybdenum carbide structures produced by spark plasma sintering

  • Can Cekli and Gultekin Goller
Published/Copyright: October 23, 2019
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International Journal of Materials Research
From the journal International Journal of Materials Research Volume 110 Issue 11

Abstract

Pure molybdenum is one of the most important refractory metals owing to its high melting point, low thermal expansion coefficient and good thermal conductivity. Molybdenum carbide exhibits superior wear resistance to molybdenum owing to its low friction coefficient and high hardness; therefore, in this study, to endure abrasive conditions, the surface of molybdenum was modified as molybdenum carbide. In accordance with this purpose, pure molybdenum powder was sintered under constant pressure (40 MPa), various temperatures (1 650 °C, 1 700 °C and 1 725 °C) and holding periods (180 s, 360  s and 540 s) using the spark plasma sintering technique. The effects of sintering temperature and holding period on relative density, microhardness, microstructure and wear properties of the specimens were investigated. Moreover, carbide formation on the surface due to carbon diffusion was also investigated. Relative density values decreased with increasing sintering temperature and period, obtaining the highest value of 97.55 % at 1 650 °C and 180 s. A microhardness value of 15.20 GPa was reached on the surface while the maximum value measured at the cross-section was 2.17 GPa, showing the formation of molybdenum carbide structure on the surface of all specimens. Furthermore, microstructural analysis supported the microhardness results and showed a minimum 288-μm thick molybdenum carbide layer on the surface. In addition, a typical eutectic microstructure was observed between molybdenum and molybdenum carbide layers; however, the decrease in temperature decreased the thickness of the eutectic layer and it gradually disappeared from the centre to edge of disc-shaped specimens. Wear resistance of surfaces was improved by decreasing holding period where a non-porous carbide layer and highest microhardness values were achieved. The cross-sectional analysis corresponding to molybdenum base metal proved that the formation of molybdenum carbide layer because of carbon diffusion improved the wear properties of the sample with the low friction coefficient and low wear depth.

Keywords: Molybdenum; Molybdenum carbide; Spark plasma sintering; Wear behavior
Correspondence address, Gultekin Goller, Department of Metallurgical and Materials Engineering, Istanbul Technical University, 34469 Istanbul, Turkey, Tel.: +90 212 2856891, Fax: +90 212 2853427, E-mail: , Web: www.biomaterials.itu.edu.tr

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Received: 2018-12-19
Accepted: 2019-05-17
Published Online: 2019-10-23
Published in Print: 2019-11-12

© 2019, Carl Hanser Verlag, München

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https://doi.org/10.3139/146.111832
Keywords for this article
Molybdenum; Molybdenum carbide; Spark plasma sintering; Wear behavior

Articles in the same Issue

  1. Contents
  2. Contents
  3. Editorial
  4. Note from the Editor-in-Chief
  5. Original Contributions
  6. The softening factor cb of commercial titanium alloy wires
  7. A comparative assessment of cyclic deformation behavior of SA333 Gr-6 steel at ambient and elevated temperatures
  8. Effects of Ni and Al on the Cu-precipitation in ferritic Fe–Cu–M (M = Ni or Al) alloy
  9. Effect of manganese on the microstructure and mechanical properties of magnesium alloys
  10. Effect of heat treatment and extrusion on wear properties of AZ91-Pr alloy
  11. Effect of anodization treatment on the mechanical properties and fatigue behavior of AA2017-T4 aluminum alloy Al–Cu–Mg1
  12. Microstructural and tribological characterization of molybdenum–molybdenum carbide structures produced by spark plasma sintering
  13. Investigation of indentation and dry sliding wear behaviour of Al-12.6 wt.% Si-10 wt.% TiB2 composites produced by sequential milling and pressureless sintering
  14. Enthalpies of mixing in ternary Ce–Cu–Sb liquid alloys
  15. Effect of in-situ formation of AlP on solidification of hypereutectic Al–Si alloy
  16. Complex-shaped high speed steel with high mechanical performance fabricated by gelcasting sintering
  17. Internal electromagnetic stirring method for preparing a large-sized aluminum alloy billet
  18. DGM News
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