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434 CHAPTER 16 Degradation of protective PVD coatings

Although a lot of investigations were performed in the literature, in which same
relation between deposition parameters and coating properties, and also between
coating properties and erosion resistance were obtained, and in most cases it was
proved that the deposition of PVD coatings improves fatigue strength and erosion
resistance, any specific PVD coating-substrate systems exposed to a specific kind
of erosion or fatigue requires further detailed experimental studies.

REFERENCES
[1] Andrievski RA. Nanostructured superhard films as typical nanomaterials. Surf Coat
Technol 2007;201:6112–6.
[2] Inspektor A, Salvador PA. Architecture of PVD coatings for metalcutting applications:
a review. Surf Coat Technol 2014;257:138–53.
[3] Mayrhofer PH, Mitterer C, Hultman L, Clemens H. Microstructural design of hard coat-
ings. Prog Mater Sci 2006;51:1032–114.
[4] Navinsek B, Panjan P, Milosev I. PVD coatings as an environmentally clean alternative
to electroplating and electroless processes. Surf Coat Technol 1999;116–119:476–87.
[5] Sproul WD. Physical vapor deposition tool coatings. Surf Coat Technol 1996;81:1–7.
[6] Van Stappen M, Stals LM, Kerkhofs M, Quaeyhaegens C. State of the art for the indus-
trial use of ceramic PVD coatings. Surf Coat Technol 1995;74–75:629–33.
[7] Gleiter H. Nanostructured materials: basic concepts and microstructure. Acta Mater
2000;48:1–29.
[8] Ahlgren M, Blomqvist H. Influence of bias variation on residual stress and texture in
TiAlN PVD coatings. Surf Coat Technol 2005;200:157–60.
[9] Barata A, Cunha L, Moura C. Characterisation of chromium nitride films produced by
PVD techniques. Thin Solid Films 2001;398–399:501–6.
[10] Bhowmick S, Jayaram V, Biswas SK. Deconvolution of fracture properties of TiN films
on steels from nanoindentation load–displacement curves. Acta Mater
2005;53:2459–67.
[11] Brizuela M, Garcia-Luis A, Braceras I, Onate JI, Sanchez-Lopez JC, Martinez-
Martinez D, et al. Magnetron sputtering of Cr(Al)N coatings: mechanical and tribolog-
ical study. Surf Coat Technol 2005;200:192–7.
[12] Herr W, Matthes B, Broszeit E, Kloos KH. Fatigue performance and tribological prop-
erties of r.f. sputtered TiN coatings. Surf Coat Technol 1993;57:43–6.
[13] Ichimura H, Ando I. Mechanical properties of arc-evaporated CrN coatings: part I—
nanoindentation hardness and elastic modulus. Surf Coat Technol 2001;145:88–93.
[14] Lang F, Yu Z. The corrosion resistance and wear resistance of thick TiN coatings depos-
ited by arc ion plating. Surf Coat Technol 2001;145:80–7.
[15] Mayrhofer PH, Tischler G, Mitterer C. Microstructure and mechanical/thermal proper-
ties of Cr-N coatings deposited by reactive unbalanced magnetron sputtering. Surf Coat
Technol 2001;142–144:78–84.
[16] Mo JL, Zhu MH. Tribological oxidation behaviour of PVD hard coatings. Tribol Int
2009;42:1758–64.
[17] Ode ´n M, Ericsson C, Ha ˚kansson G, Ljungcrantz H. Microstructure and mechanical
behaviour of arc-evaporated Cr-N coatings. Surf Coat Technol 1999;114:39.

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