Complex Behavior of Nano-Scale Tribo-Ceramic Films in Adaptive PVD Coatings under Extreme Tribological Conditions

Experimental investigations of nano-scale spatio-temporal effects that occur on the friction surface under extreme tribological stimuli, in combination with thermodynamic modeling of the self-organization process, are presented in this paper. The study was performed on adaptive PVD (physical vapor d...

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Bibliographic Details
Published in:Entropy (Basel, Switzerland) Switzerland), 2018-12, Vol.20 (12), p.989
Main Authors: Fox-Rabinovich, German, Kovalev, Anatoly, Gershman, Iosif, Wainstein, Dmitry, Aguirre, Myriam, Covelli, Danielle, Paiva, Jose, Yamamoto, Kenji, Veldhuis, Stephen
Format: Article
Language:English
Subjects:
Adhesives
Ceramic coatings
Cutting force
Cutting tools
Cutting wear
Electron microscopy
Friction
Friction reduction
H13 ultra-speed milling machining
Heat conductivity
Inequality
Multilayers
Operating temperature
Photoelectrons
Physical vapor deposition
self-organized systems
Stimuli
Surface layers
Thermal conductivity
Thermodynamic models
tribo-ceramic films
Tribology
X ray photoelectron spectroscopy
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Summary:Experimental investigations of nano-scale spatio-temporal effects that occur on the friction surface under extreme tribological stimuli, in combination with thermodynamic modeling of the self-organization process, are presented in this paper. The study was performed on adaptive PVD (physical vapor deposited) coatings represented by the TiAlCrSiYN/TiAlCrN nano-multilayer PVD coating. A detailed analysis of the worn surface was conducted using scanning electron microscopy and energy dispersive spectroscopy (SEM/EDS), transmission electron microscopy (TEM), X-ray photoelectron spectroscopy (XPS), and Auger electron spectroscopy (AES) methods. It was demonstrated that the coating studied exhibits a very fast adaptive response to the extreme external stimuli through the formation of an increased amount of protective surface tribo-films at the very beginning of the running-in stage of wear. Analysis performed on the friction surface indicates that all of the tribo-film formation processes occur in the nanoscopic scale. The tribo-films form as thermal barrier tribo-ceramics with a complex composition and very low thermal conductivity under high operating temperatures, thus demonstrating reduced friction which results in low cutting forces and wear values. This process presents an opportunity for the surface layer to attain a strong non-equilibrium state. This leads to the stabilization of the exchanging interactions between the tool and environment at a low wear level. This effect is the consequence of the synergistic behavior of complex matter represented by the dynamically formed nano-scale tribo-film layer.
ISSN:1099-4300
1099-4300
DOI:10.3390/e20120989