Growth, structure and friction behavior of the nanocomposite hard coatings WS2-Ti

Main Article Content

Thomas W. Scharf
Federico Sequeda Osorio
Juan Manuel González Carmona
Alexander Ruden
Johan Restrepo

Keywords

Superlubrication, WS2-Ti, Raman, Pin on disk.

Abstract

Tungsten disulphide (WS2) and titanium doped tungsten disulphide (Ti-WS2) nanocomposites were deposited on silicon substrates, varying substrate temperature and target power, using magnetron co–sputtering in order to obtain different Ti contents in the nanocomposite. The films were analyzed using X-ray difraction (XRD), high resolution scanning electron micrscopy (HRSEM/EDS) and high resolution transmision electron microscopy (HRTEM) to observe the crystallinity and morphology behavior respect the induced Ti percentage and the substrate temperature variation. The inclusion of Ti on the co–sputtering process prevents the WS2 crystallization forming dispersed amorphous nanocrystals (1-3 nm). The friction tests performed in a Pin on Disk (POD) at low temperatures, shows that the room temperature and low Ti concentrations films (between 5 and 14%at) possesses higher life times that pure WS2 films but no significant changes in friction coefficients (COF) were observed. The same effect is determined in high temperature POD tests (500◦C) with higher changes in COF. To study solid lubricant mechanisms, samples prepared by focus ion bean (FIB), were analyzed by Raman spectroscopy, determining surface deformation and tribo-chemical compounds formation in the wear track. The formation of WO3 in the surface during wear (tribo–oxidation) and transfer to the counterface (third body generation) was observed. Ti doping, producing a nanocomposite, is a procedure that improves tribological properties of the material in humid and high temperature environments. Obtaining these improvements by means of element doping has been poorly studied in detail and a reaction mechanism is presented allowing the phenomena explanation using advanced novel analysis techniques like FIB.

PACS: 31.15.E, 81.15.-z

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References

[1] T. J. Spalvins. A review of recent advances in solid film lubrication. Journal of Vacuum Science & Technology A: Vacuum, Surfaces, and Films, ISSN 0734–2101, 5(2), 212–219 (1987).

[2] A. A. Voevodin and J. S. Zabinski. Supertough wear–resistant coatings with chameleon surface adaptation. Thin Solid Films, ISSN 0040–6090, 370(1), 223–231 (2000).

[3] S. V. Prasad, N. T. McDevitt and J. S. Zabinski. Tribology of tungsten disulfide–nanocrystalline zinc oxide adaptive lubricant films from ambient to 500◦C. Wear, ISSN 0043–1648, 237(2), 186–196 (2000).

[4] A. Ennaoui, K. Diesner, S. Fiechter, J. H. Moser and F. L´evy. Structural analysis of 2H–WS2 thin films by X-ray and TEM investigation. Thin Solid Films, ISSN 0040–6090, 311(1–2), 146–150 (1997).

[5] A. K. Rai, R. S. Bhattacharya, J. S. Zabinski and K. Miyoshi. A comparison of the wear life of as–deposited and ion–irradiated WS2 coatings. Surface and Coatings Technology, ISSN 0257–8972, 92(1–2), 120–128 (1997).

[6] J. Jebaraj Devadasana, C. Sanjeeviraja and M. Jayachandranb. Electrosynthesis and characterisation of n-WSe2 thin films. Materials Chemistry and Physics, ISSN 0254–0584, 77(2), 397–401 (2003).

[7] J. H. Wu, D. A. Rigney, M. L. Falk, J. H. Sanders, A. A. Voevodin and J. S. Zabinski. Tribological behavior of WC/DLC/WS2 nanocomposite coatings. Surface and Coatings Technology, ISSN 0257–8972, 188(x), 605–611 (2004).

[8] T. Tsrilina, S. Cohen, H. Cohen, L. Sapir, M. Peisach, R. Tenne, A. Matthaeus, S. Tiefenbacher, W. Jaegermann, E. A. Ponomarev and C. L. Clement. Growth of crystalline WSe2 and WS2 films on amorphous substrate by reactive (Van der Waals) rheotaxy. Solar Energy Materials and Solar Cells, ISSN 0927–0248, 44(4), 457–470 (1996).

[9] S. V. Prasad, J. S. Zabinski and N. T. McDevitt. Friction behavior of pulsed laser deposited tungsten disulfide films. Tribology Transactions, e-ISSN 1547-397X, p-ISSN 1040-2004, 38(1), 57–62 (1995).

[10] A. A. Voevodin, T. A. Fitz, J. J. Hu and J. S. Zabinski. Nanocomposite tribolo- gical coatings with chameleon surface adaptation. Journal of Vacuum Science & Technology A: Vacuum, Surfaces, and Films, ISSN 0734–2101, 20(4), 1434–1444 (2002).

[11] C. C. Baker, R. R. Chromik, K. J. Wahl, J. J. Hu and A. A. Voevodin. Preparation of chameleon coatings for space and ambient environments. Thin Solid Films, ISSN 0040–6090, 515(17), 6737–6743 (2007). Referenciado en 162

[12] D. G. Teer. New solid lubricant coatings. Wear, ISSN 0043–1648, 251(1–12), 1068–1074 (2001).

[13] H. E. Sliney. Solid lubricant materials for high temperatures a review. Tribology International, ISSN 0301–6795, 15(5), 303–315 (1982).

[14] A. A. Voevodin, J. P. O’Neill and J. S. Zabinski. Nanocomposite tribological coatings for aerospace applications. Surface and Coatings Technology, ISSN 0257– 8972, 116–119, 36–45 (1999).

[15] L. Vergara, O. S´anchez and J. M. Albella. TixSiyN nanocomposites by cathodic arc plasma deposition. Vacuum, ISSN 0042–207X, 83(10), 1233–1235 (2009).

[16] H. Z.Wu, S. G. Roberts, G. M¨obus and B. J. Inkson. Subsurface damage analysis by TEM and 3D FIB crack mapping in alumina and alumina/5vol.%SiC nanocomposites. Acta Materialia, ISSN 1359–6454, 51(1), 149–162 (2003).

[17] N. Fateh, G. A. Fontalvo, G. Gassner and C. Mitterer. Influence of hightemperature oxide formation on the tribological behaviour of TiN and VN coatings. Wear, ISSN 0043–1648, 262(9–10), 1152–1158 (2007).

[18] G. Gassner, P. H. Mayrhofer, K. Kutschej, C. Mitterer and M. Katherin. Magnéli phase formation of PVD Mo–N and W–N coatings. Surface and Coatings Technology, ISSN 0257–8972, 201(6), 3335–3341 (2006).

[19] N. M. Renevier, V. C. Fox, D. G. Teer and J. Hampshire. Coating characteristics and tribological properties of sputter–deposited MoS2/metal composite coatings deposited by closed field unbalanced magnetron sputter ion plating. Surface and Coatings Technology, ISSN 0257–8972, 127(1), 24–37 (2000).

[20] K. J. Wahl, L. E. Seitzman, R. N. Bolster and I. L. Singer. Low–friction, high–endurance, ion–beam–deposited Pb–Mo–S coatings. Surface and Coatings Technology, ISSN 0257–8972, 73(3), 152–159 (1995).

[21] J. S. Zabinski, M. S. Donley, V. J. Dyhouse and N. T. McDevitt. Chemical and tribological characterization of PbO–MoS2 films grown by pulsed laser deposition. Thin Solid Films, ISSN 0040–6090, 214(2), 156–163 (1992).

[22] N. M. Renevier, J. Hamphire, V. C. Fox, J. Witts, T. Allen and D.G. Teer. Advantages of using self–lubricating, hard, wear–resistant MoS2–based coatings. Surface and Coatings Technology, ISSN 0257–8972, 142–144, 67–77 (2001).

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