Tribomechanical properties of hard Cr-doped DLC coatings deposited by low-frequency HiPIMS

Cr-doped diamond-like carbon (Cr-DLC) films with Cr contents ranging from 3 up to 20 at. % were synthesised in a codeposition process with HiPIMS (Cr deposition) and DC-pulsed technology (C deposition). The application of HiPIMS at low frequencies was observed to significantly enhance the energy den...

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Published in:Surface & coatings technology 2020-01, Vol.382, p.1, Article 124899
Main Authors: Santiago, J.A., Fernández-Martínez, I., Sánchez-López, J.C., Rojas, T.C., Wennberg, A., Bellido-González, V., Molina-Aldareguia, J.M., Monclús, M.A., González-Arrabal, R.
Format: Article
Language:English
Subjects:
Bombardment
Chromium
Coatings
Codeposition
Diamond-like carbon (DLC)
Diamond-like carbon films
Electron energy loss spectroscopy
Flux density
Graphitization
Hard coatings
Hardness
High temperature
High-temperature tribology
HiPIMS
Low frequencies
Mechanical properties
Metal-doped DLC
Modulus of elasticity
Nanoindentation
Nanostructures
Plasma jets
Room temperature
Structural analysis
Tribology
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cited_by cdi_FETCH-LOGICAL-c482t-479737f4857faf62a2289b0a590022a1f8dcdbf1ddd494cb3d3b4df139ece37d3
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container_title Surface & coatings technology
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creator Santiago, J.A.
Fernández-Martínez, I.
Sánchez-López, J.C.
Rojas, T.C.
Wennberg, A.
Bellido-González, V.
Molina-Aldareguia, J.M.
Monclús, M.A.
González-Arrabal, R.
description Cr-doped diamond-like carbon (Cr-DLC) films with Cr contents ranging from 3 up to 20 at. % were synthesised in a codeposition process with HiPIMS (Cr deposition) and DC-pulsed technology (C deposition). The application of HiPIMS at low frequencies was observed to significantly enhance the energy density during the Cr plasma discharge due to the interaction of Cr–C species. The higher energy bombardment at low HiPIMS frequencies allowed doping with Cr the DLC structure avoiding the graphitization of the carbon structure. EELS spectroscopy was used to evaluate sp3 content and Raman was used for sp2 structural characterization of the films. Enhanced mechanical properties (hardness up to 30 GPa) were observed with nanoindentation for Cr-doped DLC at low frequencies. High temperature nanoindentation tests were also performed from room temperature to 425 °C in order to evaluate the evolution of hardness and Young Modulus with temperature. The results showed that the mechanical properties at high temperature mainly depend on the initial sp3-sp2 structure. Tribological tests were carried out in air from room temperature to 250 °C. Cr-doped DLC coatings deposited by low-frequency HiPIMS showed lower friction and wear compared to undoped DLC. •Cr-doped DLC coatings were co-deposited by low-frequency/high current HiPIMS method.•Cr doping by low frequency HiPIMS preserves DLC sp3 content and reduces compressive stress.•Low at. % Cr-doped DLC exhibit high hardness (up to 29 GPa) and delayed graphitization (up to 400 C).•Low at. % Cr-doped DLC presents enhanced tribological behaviour at high temperatures by creating stable tribolayers.
doi_str_mv 10.1016/j.surfcoat.2019.124899
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The application of HiPIMS at low frequencies was observed to significantly enhance the energy density during the Cr plasma discharge due to the interaction of Cr–C species. The higher energy bombardment at low HiPIMS frequencies allowed doping with Cr the DLC structure avoiding the graphitization of the carbon structure. EELS spectroscopy was used to evaluate sp3 content and Raman was used for sp2 structural characterization of the films. Enhanced mechanical properties (hardness up to 30 GPa) were observed with nanoindentation for Cr-doped DLC at low frequencies. High temperature nanoindentation tests were also performed from room temperature to 425 °C in order to evaluate the evolution of hardness and Young Modulus with temperature. The results showed that the mechanical properties at high temperature mainly depend on the initial sp3-sp2 structure. Tribological tests were carried out in air from room temperature to 250 °C. Cr-doped DLC coatings deposited by low-frequency HiPIMS showed lower friction and wear compared to undoped DLC. •Cr-doped DLC coatings were co-deposited by low-frequency/high current HiPIMS method.•Cr doping by low frequency HiPIMS preserves DLC sp3 content and reduces compressive stress.•Low at. % Cr-doped DLC exhibit high hardness (up to 29 GPa) and delayed graphitization (up to 400 C).•Low at. % Cr-doped DLC presents enhanced tribological behaviour at high temperatures by creating stable tribolayers.</abstract><cop>Lausanne</cop><pub>Elsevier B.V</pub><doi>10.1016/j.surfcoat.2019.124899</doi><oa>free_for_read</oa></addata></record>
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source ScienceDirect Freedom Collection 2022-2024
subjects Bombardment
Chromium
Coatings
Codeposition
Diamond-like carbon (DLC)
Diamond-like carbon films
Electron energy loss spectroscopy
Flux density
Graphitization
Hard coatings
Hardness
High temperature
High-temperature tribology
HiPIMS
Low frequencies
Mechanical properties
Metal-doped DLC
Modulus of elasticity
Nanoindentation
Nanostructures
Plasma jets
Room temperature
Structural analysis
Tribology
title Tribomechanical properties of hard Cr-doped DLC coatings deposited by low-frequency HiPIMS
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