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Tribological coatings are mainly used to reduce adhesive wear, which often leads to the seizure or the formation of cold welds. The low coefficient of friction and good sliding properties make it ideal for applications with low lubrication or even dry running. The result is an ideal way to reduce surface fatigue and tribo-oxidation. Tribological coatings have good sliding properties, a low coefficient of friction and low adhesive wear. Thin layers of WC/C and TiC/C of the MeC/a-C: H coating group were deposited onto the surface of ISO 683/11-70 steel. The third tribological coating deposited on the same substrate was a ta-C coating – a tetrahedral amorphous layer (stoichiometry: sp3 bonds > 50%). Tribological measurements were performed at a load of 10 N, a rotational speed of 60 rpm, and with a counterpart of ceramic material Al2O3.1. INTRODUCTIONThin coatings are used to protect the substrate and improve the useful properties of components. Insufficient lubrication and dry friction can occur during the working process. Therefore, thin layers can be applied (deposited on a certain substrate), which can perform the function of a lubricant [1]. The addition of metal to the carbon layers can in some cases improves the mechanical and tribological properties [2], for example a thin layer of WC/C that provides, chemical inertness and low coefficient of friction (0.12 to 0.15) [3]. WC/C coatings offer good adhesion to the base substrate, which is an integral part of industrial use [1] and a large modulus of elasticity [4]. WC/C layers contain a nanocrystalline WC layer with and an amorphous C phase [4]. Tungsten carbide with amorphous carbon is used in technical applications such as bearings, pumps, compressors, gear wheels, tools, [5] for anti-corrosion components, and to protect aircraft engine components etc. [6]. DLC layers are used in hard drives, shavers, damage-resistant glass, electronics, medicine and the automotive industry [7, 8]. There are different types of DLC layers, which differ in composition, method of preparation and properties. One type of DLC layer is a ta-C coating, which has a low coefficient of friction and is wear resistant [9]. Diamond-like tetrahedral amorphous carbon (ta-C) films, which contain no hydrogen and high content of sp3 bonds, have a very high hardness and elastic modulus (up to 600 GPa) [10]. TiC/C coatings have good sliding properties and is wear resistant. This type of coating is used as a protective coating with high hardness and toughness [11]. Mechanical and tribological properties are influenced by deposition conditions [12, 13]. The modulus of elasticity of TiC/C thin films ranges from 160 to 430 GPa, nanohardness from 13 to 44 GPa and the coefficient of friction is around 0.14. TiC/C coatings are suitable for application on tools or machine parts [1].The aim of this research is to improve the utility properties of surfaces after modification of basic materials with thin layers labeled ta-C, WC/C and TiC/C. Surfaces after modification are intended to provide better friction properties in contact with the counter-body during dry friction. The surface modification with the desired frictional properties was subsequently selected as suitable for a given industrial application.2. MATERIALS AND METHODS2.1 Used thin layersFor the experiment, thin carbon-based coatings: ta-C, WC/C and TiC/C (SHM s.r.o. and PLATIT a.s.) were applied on two steel substrates W.Nr. 1.7131 (with a hardness of 650 HV1) and W.Nr. 1.2379 (with a hardness of 730 HV1). The surface roughness and morphology, nanohardness, adhesion to the base material, wettability, homogeneity, thickness of coatings, tribological behavior and amount of wear were evaluated on the prepared coatings. Table 1 shows the deposition conditions of the investigated thin coatings. PVD technologies used by SHM s.r.o. are based on two basic coating principles: low-voltage arc vapor deposition and magnetron sputtering. All thin films used in the research were applied by magnetron sputtering.Table 1 Thin coating deposition conditions2.2 Used methods of thin film evaluationThe nanohardness and elastic modulus of the coatings were evaluated by a CSM Instruments indentation tester (Berkovich evaluation method). The maximum penetration depth during the measurement was no more than 10 % of the coating thickness.A Zeiss Ultra Plus scanning electron microscope (SEM) equipped with an Oxford X-Max 20 energy dispersive spectrometer (EDS) was used for the local chemical analysis, homogeneity, and thickness of the thin layers. To minimize the influence of the substrate on the quant results due to the penetration of primary electrons through the deposited layers, the chemical composition of the layers was analyzed at an accelerating voltage of 10 kV. Before performing the SEM analysis, the samples were cleaned with a mixture of ethanol and water in an ultrasonic cleaner.The coating surface morphology was evaluated using a Sensofar Metrology material confocal microscope according to the ISO 25178 standard. The used parameters were as follows: Sa is the average arithmetic height (average surface roughness); Sz is the maximum height (height between the lowest recesses and the highest projection). The size of the evaluated area was 1700.16 x 1418.64 μm.The coating adhesion was evaluated using a CETR UMI Multi-Specimen Test System. A scratch test was performed using a progressive load from 2 to 80 N at a speed of 10 mm/min (according to the EN1071-3:2005 standard). The scratch test was performed at room temperature and a relative humidity of 36 ± 2 %.The wettability of the nanostructured coatings was investigated on a Surface Energy Evaluation system, which is designed primarily for contact angle measurement and determination of surface energy. It features a robust aluminum housing, a 1.3 Mpx USB 2.0 color camera that moves vertically, and a 2D horizontal sample table. Distilled water was used for the evaluation and the tested oil with the trade name Paramo CLP 320 was used to approach the real conditions. The wettability evaluation apparatus was prepared according to the planned methodology and the samples were handled using gloves. The room temperature during the measurement was 22°C, the air humidity was 36 ± 2% and the drop volume used was 5 µL. Ten drops were dripped onto each of the investigated surfaces to ensure repeatability.A tribometer for dry and liquid environments (Anton Paar Czech Republic s.r.o.) in the “Ball-on-Disc” mode was used to estimate the tribology properties of the thin coatings (ASTM G99-95). An essential part of the test measurement was a friction sensor. The coefficient of friction (CoF) between the unit and the disc was determined during the test measurement. Tribological testing was conducted using a ball made of Al2O3 with a diameter of 6.00 mm, at a load of 10 N and at room temperature and a humidity of 34 ± 2 %. The rotation speed during the experiment was 60 rpm and the travelled distance was 500 m.3. RESULTS3.1 Morphology a surface roughnessFigure 1 shows the surface morphology of the investigated coatings labeled amorphous carbon (ta-C), WC/C and TiC/C by SEM analysis.The measured surface roughness values (see Table 2) show that the modification of the surface leads to an increase in its roughness (according to the parameters Sa and Sz). The greatest influence on the increase of surface roughness compared to the roughness of the base material was measured on the surface of the coating labeled TiC/C (W.Nr. 1.7131), then on the surface of the coatings labeled ta-C (W.Nr. 1.2379) and TiC/C (W.Nr. 1.2379).Table 2 The measured surface roughness values Sa and Sz and their standard deviations in [μm]3.2 Hardness and modulus of elasticityThe parameters of the process of evaluation of nanohardness were as follows: approach distance 2 μm; linear loading with approach speed 1 μm/min; max depth 0.30 μm; retract speed 2 μm/min; loading rate 1.00 μm/min; unloading rate 1.00 μm/min; stiffness threshold 500 μN/μm. Table 3 shows averaged values from five measurements of the hardness, modulus of elasticity and the plasticity index (H/E).Table 3 The values of nanohardness and elastic modulus of the coatings in [GPa]The applied thin coatings significantly increased the base surface hardness; the highest nanohardness values were measured for the thin coatings labeled ta-C (24 – 33 GPa) and TiC/C (26 – 28 GPa), see Table 3.3.3 Scratch test resultsThree measurements were taken at different points for each sample, and the average values of the measured critical loads (LC) are given in Table 4. Based on the scratch tests, the critical load corresponding to a load leading to the appearance of the first crack LC1 (cohesive failure) lied within the range of 16 – 22 N, and the next critical load LC3 (adhesion failure) lied within the range of 45 – 59 N.Table 4 The adhesion properties of the investigated coatings in [N]The measured adhesion values show that all of the types of surface modification have very good adhesion to the base material (W.Nr. 1.7131 and W.Nr. 1.2379). The best adhesion properties were measured with the thin coating of amorphous carbon (ta-C) on both types of substrate.3.4 Evaluation of the wettability of nanocomposite surfacesThe wettability evaluation was performed according to the described methodology and the measurement results together with the standard deviation are shown in Table 5.Table 5 Measured values of contact angle on the surface of the investigated coatings in [°]The measured values indicate surfaces with hydrophilic properties, contact angles using distilled water and oil with the trade name Paramo CLP 320 were less than 90°.3.5 Homogeneity and thickness of the thin coatingsThe thickness and homogeneity of the coatings was evaluated from their cuts (Fig. 2). The evaluation was performed by linear and area analysis of chemical composition and using an SE detector.The ta-C, WC/C, TiC/C coatings were cast into the resin and polished with diamond paste, and the ta-C layers had to be silver plated. The thin layers deposited on the steel substrates (W.Nr. 1.7131 and W.Nr. 1.2379) are highly homogeneous. No major defects or cracks were observed on the coatings or on the boundaries of the coatings - substrate.3.6 Tribological behavior and surface wear rateA comparison of the changes in friction coefficients is made firstly by contacting the observed coatings with an Al2O3 ceramic ball. Furthermore, the nanostructured surfaces were evaluated using a lubricating medium (Paramo CLP 320), while the counterpart remained of the same material (Al2O3). The working temperature of the oil during the tribological experiment was 45°C. The last part of the experiment was conducted with the addition of the Paramo CLP 320 oil with nanoparticles (SiO2 NPs and SiO2 + Al2O3 NPs at a concentration of 0.5 g/L) under the same conditions.Table 6 Measured values of coefficient of friction and their standard deviationsThe evaluation of the coefficient of friction in the lubricating medium Paramo CLP 320 (Fig. 3 left) with the addition of SiO2 NPs (Fig. 3 center) and SiO2 + Al2O3 NPs (Fig. 3 right) was performed on thin layers of ta-C and WC/C, the layers showed the lowest values of CoF during dry friction. Figure 3 shows the amount of wear of the thin coatings labeled ta-C upon contact with the Al2O3 ceramic ball and use of oil with and without nanoparticle additivation.Lubricant friction had a beneficial effect on the CoF and wear of the friction pair. It was further determined that the nanoparticles had no effect on the size of the CoF (see Table 6). The addition of the SiO2 NPs to the lubricant (Paramo CLP 320) had a positive impact on the wear process, resulting in a reduction in the size of the damaged area after tribology (Fig. 3 – right). Conversely, the combination of nanoparticles (SiO2 + Al2O3 NPs) resulted in increased wear after the tribological process (Fig. 3 – center) compared to the oil without additivation.4. CONCLUSIONThree types of thin coatings (ta-C, WC/C and TiC/C) applied by low-voltage arc vapor deposition and magnetron sputtering were investigated. The study led to the following conclusions:Modification of the material surface with thin coatings leads to a slight increase in surface roughness.After the application of the thin coatings there was a significant increase in hardness on the surface of the test samples.The best adhesion to the base material was shown by the coating labeled ta-C for both types of base material.The applied thin layers did not affect the wettability of the base material surfaces; the PARAMO CLP 320 oil used has a good surface wettability.The deposited thin coatings of ta-C, WC/C and TiC/C on the substrates reduced the CoF by up to 85 %. The coatings labeled ta-C and WC/C in combination with the PARAMO lubricant with SiO2 NP additivation resulted in the best results, i.e. lower CoF and reduced wear.AcknowledgementsThis paper was supported through the project “Special transformation mechanisms in drives with electronic cams” Registration Number FV20547, obtained through the financial support of the Ministry of Industry and Trade in the program MIT TRIO and the Technical University of Liberec as part of the project of the Technical University of Liberec, Faculty of Mechanical Engineering with the support of the Institutional Endowment for the Long Term Conceptual Development of Research Institutes, as provided by the Ministry of Education, Youth and Sports of the Czech Republic in the year 2019. We are also grateful to PLATIT a.s. for the preparation of the thin coatings.REFERENCESWIKLUND, U., M. NORDIN. Evaluation of a flexible physical vapor deposited TiC–C coating system. 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Keywords: Nanocomposite coatings, surface morphology, mechanical properties, tribology and wear.© This is an open access article distributed under the Creative Commons Attribution License which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.