Effect of Temperature on the Structure and Tribological Properties of Ti, TiN and Ti/TiN Coatings Deposited by Cathodic Arc PVD

Monolayers of Ti and TiN coatings, as well as a Ti/TiN bilayer coating, were deposited on AISI M2 steel substrates using the PVD cathodic arc technique. The coatings had a thickness close to 5 μm and an average roughness between 98.6 and 110.1 μm due to the presence of microdroplets on the surface....

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Bibliographic Details
Published in:Coatings (Basel) 2024-07, Vol.14 (7), p.823
Main Authors: Ortega-Portilla, Carolina, Giraldo, Andrea, Cardona, Jorge Andrés, Ruden, Alexander, Mondragón, Guillermo César, Trujillo, Juan Pablo, Gómez Ortega, Arturo, González-Carmona, Juan Manuel, Franco Urquiza, Edgar Adrián
Format: Article
Language:English
Subjects:
Abrasion
Analysis
Anatase
Arc deposition
Bilayers
Coatings
Corrosion
Crystal structure
Crystals
Cutting tools
Diffraction
Dynamic structural analysis
Friction
High speed tool steels
High temperature
Mechanical properties
Metal forming
Oxidation
Oxides
Phase composition
Phase transitions
Pin on disk tests
Protective coatings
Rietveld method
Rutile
Structure
Substrates
Temperature
Temperature effects
Thickness
Titanium
Titanium nitride
Titanium oxides
Tribology
X-rays
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Summary:Monolayers of Ti and TiN coatings, as well as a Ti/TiN bilayer coating, were deposited on AISI M2 steel substrates using the PVD cathodic arc technique. The coatings had a thickness close to 5 μm and an average roughness between 98.6 and 110.1 μm due to the presence of microdroplets on the surface. The crystalline structure of the materials was analyzed using Grazing Incidence X-ray Diffraction (GIXRD) with an increase in temperature to study the dynamics of oxide formation. A phase composition study was conducted using the Rietveld refinement method. At the temperatures where critical growth of titanium oxides, both anatase and rutile, was observed, pin-on-disk tests were performed to study the tribological properties of the materials at high temperatures. It was determined that the oxidation temperature of Ti is around 450 °C, promoting the formation of a combination of anatase and rutile. However, the formation of rutile inhibits the formation of anatase, which is stable above 600 °C. In contrast, TiN showed an oxidation temperature of 550 °C, with an exclusive growth of the rutile phase. The Ti/TiN bilayer exhibited mixed behavior, with the initial growth of anatase promoted by Ti, followed by the formation of rutile. Oxidation and tribo-oxidation dominated the wear behavior of the surfaces, showing a transition from mechanisms related to abrasion at low and medium temperatures to a combination of abrasion and adhesion mechanisms at high temperatures (800 °C).
ISSN:2079-6412
2079-6412
DOI:10.3390/coatings14070823