Microstructure and Mechanical Characteristics of the CrN/Si3N4 Multilayered Films Prepared by Sputtering

Chien Cheng Liu; Kuang I Liu; Hao Tung Lin; Yung Mao Cheng

doi:10.4028/www.scientific.net/AMR.476-478.2571

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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 476-478Microstructure and Mechanical Characteristics of...

Microstructure and Mechanical Characteristics of the CrN/Si₃N₄ Multilayered Films Prepared by Sputtering

Abstract:

Multilayers of CrN/Si3N4 coatings were prepared by magnetron sputtering on die steel substrates. The layers of CrN/Si3N4 films were varied to investigate their effects on microstructure, morphology, nano-hardness properties determined by X-ray diffraction, field-emission scanning electron microscope (FE-SEM), nanoindentation, and pin-on-disk, respectively. The result shows that CrN has highly (111) preferred orientation and Si3N4 exhibits amorphous phase at working temperature of 200 oC. The surface of coatings revealed smaller grains and uniform dense with higher layers. The number of layers increased with enhancing of the mechanical properties, and hardness values. At 64 layers films had the largest nano-hardness. Besides, the highest layers of CrN/Si3N4 multilayers have been achieved the lowest friction coefficient for against steel ball.

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Periodical:

Advanced Materials Research (Volumes 476-478)

Pages:

2571-2574

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.476-478.2571

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Online since:

February 2012

Authors:

Chien Cheng Liu, Kuang I Liu, Hao Tung Lin, Yung Mao Cheng

Keywords:

Crn/Si₃N₄ Multilayers, Friction Coefficient (FC), Magnetron Sputtering

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References

[1] W. Schintlmeister, W. Wallgram, and J. Kanz, Properties, applications and manufacture of wear-resistant hard material coatings for tools , Thin Solid Films 107 (1983) 117 -127. [2] V.V. Lyubimov, A.A. Voevodin, Y.S. Timofeev, and I.K Arkhipov, Development and testing of multilayer physically vapour deposited coatings for piston rings, Surf. Coat. Technol. 52 (1992) 145-151. [3] Y. H. Chen, M. Guruz, Y. W. Chung, and L. M. Keer, Thermal stability of hard TiN/SiNx multilayer coatings with an equiaxed microstructure, Surf. Coat. Technol. 154 (2002) 162 -166. [4] C. Subramanian, and K.N. Strafford, Review of multicomponent and multilayer coatings for tribological applications, Wear. 165 (1993) 85-95. [5] P. Panjan, B. Navinsek, A. Cvelbar, A. Zalar, and I. Milosev, Oxidation of TiN, ZrN, TiZrN, CrN, TiCrN and TiN/CrN multilayer hard coatings reactively sputtered at low temperature, Thin Solid Films 281-282 (1996) 298-301. [6] X. Chu, M.S. Wong, W.D. Sprout, and S.A. Barnett, Mechanical properties and microstructures of polycrystalline ceramic/metal superlattices: TiN/Ni and TiN/Ni0.9Cr0.1, Surf. Coat. Technol. 61 (1993) 251-262. [7] B. Warcholinski, A. Gilewicz, Z. Kuklinski, and P. Myslinski, Hard CrCN/CrN multilayer coatings for tribological applications, Surf. Coat. Technol. 204 (2010) 2289-2293. [8] I. Wadsworth, D.B. Lewis, and G. Williams, Structural studies of TiN/ZrN multilayer coating deposited by physical vapour deposition, J. Mater. Sci. 31 (1996) 5907- 5914. [9] S. Baragetti, G.M. La Vecchia, and A. Terranova, Fatigue behavior and FEM modelling of thin coated components, Int. J. Fatigue 25 (2003) 1229-1238. [10] M.J. Powell, B.C. Easton, and O.F. Hill, Amorphous silicon-silicon nitride thin film transistors, Appl. Phys. Lett. 38 (1981) 794-796. [11] B Abeles, P.D Persans, H.S Stasiewski, L Yang, W Lanford, Structure of interfaces in a-Si:H/a-Sinx:H superlattices, J. Non Cryst. Solids, 77-78 (1985) 1065-1068. [12] Y. Hirohata, N. Shimamoto, T. Hino, T. Yamashima, and K. Yabe, Properties of silicon nitride films prepared by magnetron sputtering, Thin Solid Films 253 (1994) 425-429.

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