Page 438 - Handbook of Materials Failure Analysis

P. 438

436 CHAPTER 16 Degradation of protective PVD coatings

[35] Voevodin AA, Bantle R, Matthews A. Dynamic impact wear of TiCxNy and Ti-DLC
composite coatings. Wear 1995;185:151.
[36] Wanstrand O, Larsson M, Kassman-Rudolphi A. An experimental method for evalua-
tion of the load-carrying capacity of coated aluminium: the influence of coating stiff-
ness, hardness and thickness. Surf Coat Technol 2000;127:107–13.
[37] Barna PB, Adamik M. Fundamental structure forming phenomena of polycrystalline
films and the structure zone models. Thin Solid Films 1998;317:27–33.
[38] Kluth O, Schope G, Hupkes J, Agashe C, Muller J, Rech B. Modified Thornton model
for magnetron sputtered zinc oxide: film structure and etching behavior. Thin Solid
Films 2003;442:80–5.
[39] Gahlin R, Bromark M, Hedenqvist P, Hogmark S, Hakansson G. Properties of TiN and
CrN coatings deposited at low temperature using reactive arc-evaporation. Surf Coat
Technol 1995;76–77:174–80.
[40] Harris SG, Doyle ED, Wonga Y-C, Munroe PR, Cairney JM, Long JM. Reducing the
macroparticle content of cathodic arc evaporated TiN coatings. Surf Coat Technol
2004;183:283–94.
[41] Bielawski M, Seo D. Residual stress development in UMS TiN coatings. Surf Coat
Technol 2005;200:1476–82.
[42] Grant WK, Loomis C, Moore JJ, Olson DL, Mishra B, Perry AJ. Characterization of
hard chromium nitride coatings deposited by cathodic arc vapour deposition. Surf Coat
Technol 1996;86–87:788–96.
[43] Karlsson L, Hultman L, Sundgren J-E. Influence of residual stresses on the mechanical
properties of TiC x N 1-x (x¼0, 0.15, 0.45) thin films deposited by arc evaporation. Thin
Solid Films 2000;371:167–77.
[44] Krella AK. The new parameter to assess cavitation erosion resistance of hard PVD coat-
ings. Eng Fail Anal 2011;18:855–67.
[45] Krella A, Czyz ˙niewski A. Investigation concerning the cavitation resistance of TiN coat-
ings deposited on austenitic stainless steel at various temperatures. Wear
2008;265:72–80.
[46] Krella A, Czyz ˙niewski A. Cavitation resistance of Cr–N coatings deposited on austen-
itic stainless steel at various temperatures. Wear 2009;266:800–9.
[47] Batista JCA, Godoy C, Matthews A. Impact testing of duplex and non-duplex (Ti, Al)N
and Cr–N PVD coatings. Surf Coat Technol 2003;163–164:353–61.
[48] Batista JCA, Godoy C, Pintaude G, Sinatora A, Matthews A. An approach to elucidate
the different response of PVD coatings in different tribological tests. Surf Coat Technol
2003;174–175:891–8.
[49] Ding X-Z, Zeng XT. Structural, mechanical and tribological properties of CrAlN coat-
ings deposited by reactive unbalanced magnetron sputtering. Surf Coat Technol
2005;200:1372–6.
[50] Jianxin D, Fengfang W, Yunsong L, Youqiang X, Shipeng L. Erosion wear of CrN,
TiN, CrAlN, and TiAlN PVD nitride coatings. Int J Refract Met Hard Mater
2012;35:10–6.
[51] Uchida M, Nihira N, Mitsuo A, Toyoda K, Kubota K, Aizawa T. Friction and wear
properties of CrAlN and CrVN films deposited by cathodic arc ion plating metod. Surf
Coat Technol 2004;177–178:627–30.
[52] Wang YX, Zhang S, Lee J-W, Lew WS, Li B. Influence of bias voltage on the hardness
and toughness of CrAlN coatings via magnetron sputtering. Surf Coat Technol
2012;206:5103–7.

433 434 435 436 437 438 439 440 441 442 443