Effect of coating architectures on the wear and hydrophobic properties of Al–N/Cr–N multilayer coatings

Two coating architectures with various deposition times (Dts) for each layer and N2 gas flow rate ratio η (N2/(N2+Ar)) of Al–N/Cr–N multilayer coatings were prepared using unbalanced magnetron reactive sputtering. Using the same coating process, two coating architectures were deposited on the high s...

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Bibliographic Details
Published in:Surface & coatings technology 2014-11, Vol.259, p.172-177
Main Authors: Yang, Yu-Sen, Cho, Ting-Pin, Lin, You-Chang
Format: Article
Language:English
Subjects:
Aluminum
Al–N/Cr–N coatings
Applied sciences
Architecture
Chromium
Coating
Contact of materials. Friction. Wear
Cross-disciplinary physics: materials science
rheology
Exact sciences and technology
Materials science
Mechanical properties and methods of testing. Rheology. Fracture mechanics. Tribology
Metals. Metallurgy
Multilayer coating
Phases
Physics
Production techniques
Protective coatings
Reactive sputtering
Surface treatment
Surface treatments
Water contact angle
Wear
Wear resistance
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Summary:Two coating architectures with various deposition times (Dts) for each layer and N2 gas flow rate ratio η (N2/(N2+Ar)) of Al–N/Cr–N multilayer coatings were prepared using unbalanced magnetron reactive sputtering. Using the same coating process, two coating architectures were deposited on the high speed tool steel and Si wafer, one starting with an Al–N layer designed as the Al–N/Cr–N/…/Cr–N/Al–N (architecture A) and the other starting with a Cr–N layer designed as the Cr–N/Al–N/…/Al–N/Cr–N (architecture C). During the coating process, the N2 gas flow rate ratio η was set at 15%, 20% and 25% to control the Cr–N and Al–N layer phases. This study investigates the effects of architectures, Dt and η on the wear and hydrophobic properties of the coatings. The X-ray diffraction results show that Cr(N), Cr(N)+Cr2N and Cr2N+CrN phases respectively form in the Cr–N layer given η=15%, 20% and 25%, and only the hcp-AlN phase forms in the Al–N layer. The layer thickness ratio (λ) of the Cr–N layer to the Al–N layer increases from 2.7 to 6.4 as η increases from 15 to 25%. The wear resistance of the coatings is strongly related to the coating architecture. The architecture A coatings exhibit better wear resistance than the architecture C coatings. The number of layers and layer thickness ratios λ also affects the wear behavior. In terms of the hydrophobic property, the coating architecture C with the Cr2N+CrN phase (η=25%) on the top layer shows higher water contact angle measurements of 95°–97°. •Two coating architectures with various layer deposition times and N2 flow rate ratio η were prepared.•The main phases of Cr–N layers with various η are Cr(N), Cr2N+Cr(N) and Cr2N+CrN, respectively.•The main phase of the Al–N layer is h-AlN for all values of η.•The architecture A coatings exhibit better wear resistance than the architecture C coatings.•The hydrophobic property of coatings is strongly related to the top layer phase.
ISSN:0257-8972
1879-3347
DOI:10.1016/j.surfcoat.2014.01.058