High temperature behavior of nanolayered CrAlTiN coating: thermal stability, oxidation, and tribological properties
High temperature behavior of nanolayered CrAlTiN coating: thermal stability, oxidation, and tribological properties
Hard protective nitride coatings are often applied to cutting tools operating at high temperature. To further develop and optimize their performance, in-situ investigation of structure, oxidation, mechanical and tribological properties at elevated temperature is required. In this study we focus on the high temperature behavior of a nanolayered CrAlTiN coating deposited on WC substrates by cathodic arc evaporation. The coating's chemical composition and the bonding state were evaluated by electron probe microanalysis and by X-ray photoelectron spectroscopy (XPS). The structure of as-deposited and annealed samples was analyzed using X-ray diffraction. The adhesion was investigated by scratch test and the mechanical properties were studied by depth sensing nanoindentation. The main objective of this work was to have a detailed analysis of friction and wear properties tested by high temperature tribometer (pin-on-disc) with alumina balls as counterparts in the temperature range of 20–800 °C. Selected wear track cross-sections were prepared by focused ion beam and analyzed by transmission electron microscopy; the wear track was investigated as well by XPS (chemical depth profile) and by Raman spectroscopy. The coating showed an excellent thermal stability and wear resistance. The friction reached a maximum at 500 °C and then decreased, whereas the wear rate was negligible up to 600 °C and then increased significantly for higher temperatures. Oxidation of the worn surfaces was surprisingly low even at the highest temperature corroborating results of oxidation tests. The main identified wear mechanism was polishing combined with a nanoscale delamination of thin coating layers; nanoscale multilayer proved to be a vital factor blocking vertical crack propagation.
70-77
Polcar, T.
c669b663-3ba9-4e7b-9f97-8ef5655ac6d2
Cavaleiro, A
114e42eb-7255-47ef-834d-0546d56d3171
25 October 2014
Polcar, T.
c669b663-3ba9-4e7b-9f97-8ef5655ac6d2
Cavaleiro, A
114e42eb-7255-47ef-834d-0546d56d3171
Polcar, T. and Cavaleiro, A
(2014)
High temperature behavior of nanolayered CrAlTiN coating: thermal stability, oxidation, and tribological properties.
[in special issue: 25 Years of TiAlN Hard Coatings in Research and Industry]
Surface and Coatings Technology, 257, .
(doi:10.1016/j.surfcoat.2014.07.053).
Abstract
Hard protective nitride coatings are often applied to cutting tools operating at high temperature. To further develop and optimize their performance, in-situ investigation of structure, oxidation, mechanical and tribological properties at elevated temperature is required. In this study we focus on the high temperature behavior of a nanolayered CrAlTiN coating deposited on WC substrates by cathodic arc evaporation. The coating's chemical composition and the bonding state were evaluated by electron probe microanalysis and by X-ray photoelectron spectroscopy (XPS). The structure of as-deposited and annealed samples was analyzed using X-ray diffraction. The adhesion was investigated by scratch test and the mechanical properties were studied by depth sensing nanoindentation. The main objective of this work was to have a detailed analysis of friction and wear properties tested by high temperature tribometer (pin-on-disc) with alumina balls as counterparts in the temperature range of 20–800 °C. Selected wear track cross-sections were prepared by focused ion beam and analyzed by transmission electron microscopy; the wear track was investigated as well by XPS (chemical depth profile) and by Raman spectroscopy. The coating showed an excellent thermal stability and wear resistance. The friction reached a maximum at 500 °C and then decreased, whereas the wear rate was negligible up to 600 °C and then increased significantly for higher temperatures. Oxidation of the worn surfaces was surprisingly low even at the highest temperature corroborating results of oxidation tests. The main identified wear mechanism was polishing combined with a nanoscale delamination of thin coating layers; nanoscale multilayer proved to be a vital factor blocking vertical crack propagation.
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e-pub ahead of print date: 30 July 2014
Published date: 25 October 2014
Organisations:
Engineering Mats & Surface Engineerg Gp
Identifiers
Local EPrints ID: 371855
URI: http://eprints.soton.ac.uk/id/eprint/371855
ISSN: 0257-8972
PURE UUID: 309e51e0-e5db-4d23-b75f-88769f51e466
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Date deposited: 19 Nov 2014 15:32
Last modified: 15 Mar 2024 03:40
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Author:
A Cavaleiro
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