Study of W-B-C thin films prepared by magnetron sputtering using a combinatorial approach

X-B-C materials, where X is a transition metal such as Mo, W or Ta, have recently gained attention as possible materials for protective coatings used in material machining. In this study, a combinatorial approach was used to deposit a total of 182 coatings with a wide composition range using pulsed-...

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Bibliographic Details
Published in:International journal of refractory metals & hard materials 2019-12, Vol.85, p.105066, Article 105066
Main Authors: Debnárová, S., Zábranský, L., Souček, P., Buršíková, V., Vašina, P.
Format: Article
Language:English
Subjects:
Ambient temperature
Bias
Boron
Carbon content
Combinatorial analysis
Combinatorial approach
Composition
Crystal structure
Crystallinity
Energy flow
Hardness
Machining
Magnetron sputtering
Modulus of elasticity
Protective coatings
Tantalum
Thin films
Transition metals
Tungsten
W-B-C
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Summary:X-B-C materials, where X is a transition metal such as Mo, W or Ta, have recently gained attention as possible materials for protective coatings used in material machining. In this study, a combinatorial approach was used to deposit a total of 182 coatings with a wide composition range using pulsed-DC magnetron sputtering. The coatings were prepared either in conditions, where a comparatively lower energy was delivered onto the growing coating, i.e. at ambient temperature and without applied bias, or in conditions where the coating received higher energy, i.e. at 500 °C with a bias voltage of −100 V, to study the effect of energy flow on the coating structure and properties. The coating structure was examined and four different types of diffractograms have been observed: amorphous, short range ordered, crystalline W and nanocrystalline WB2. No other crystalline phases were detected. The measured hardness of the coatings was between 9.7 and 29.7 GPa and was independent of the carbon content, however, it increased with the boron content and decreased with the tungsten content in the composition region studied. The hardest coatings exhibited an amorphous structure. The effective elastic modulus ranged from 170 to 340 GPa and increased with the boron and tungsten contents. The highest moduli were obtained for coatings exhibiting a crystalline W phase. Coatings deposited at high energy flow to the growing coating generally exhibited higher hardness and comparable elastic modulus to their counterparts with a similar composition prepared without heating or bias. •W-B-C films in a wide composition range were prepared by p-DC magnetron sputtering.•The effect of energy flow and composition on the coating properties was studied.•The studied coatings exhibited an amorphous or nanocrystalline structure.•The hardness of the coatings increased with the boron content from 9.7 to 29.7 GPa.•Coatings with high boron content exhibited enhanced fracture resistance.
ISSN:0263-4368
2213-3917
DOI:10.1016/j.ijrmhm.2019.105066